Surface Area Quotes

This is the whole problem with words. There is so little surface area to reveal whom you might be underneath, how expansive and warm, how casual, how easygoing, how cool, and so it all comes out a little pathetic and awkward and choked.

But then, Cap'n Crunch in a flake form would be suicidal madness; it would last about as long, when immersed in milk, as snowflakes sifting down into a deep fryer. No, the cereal engineers at General Mills had to find a shape that would minimize surface area, and, as some sort of compromise between the sphere that is dictated by Euclidean geometry and whatever sunken treasure related shapes that the cereal aestheticians were probably clamoring for, they came up with this hard -to-pin-down striated pillow formation.

Overpopulation has a ceiling: earth’s total surface area divided by the dimensions of one economy seat. One more baby is born and hello cannibalism.

Optically transparent, structurally sound and chemically inert, glass is a fabulous building material and has been for over four thousand years. Still, the production and use of hundreds of billions of glass facad components every year in the US alone begs the question; What if we can utilize this immense surface area for harvesting solar energy in efficient and effective ways.

Optically transparent, structurally sound and chemically inert, glass is a fabulous building material and has been for over four thousand years. Still, the production and use of hundreds of billions of glass facad components every year in the US alone begs the question; What if we can utilize this immense surface area for harvesting solar energy in efficient and effective ways? The 3D Printing of optically transparent glass points toward such a possible future.

Your 40 trillion cells contain at least a quadrillion mitochondria, with a combined convoluted surface area of about 14,000 square metres; about four football fields.

When flint strikes steel, it knocks microscopic flecks of metal into the air. The metal burns because of some complicated crap related to surface area and oxidization rates. Basically, it rusts so fast that the reaction heat makes fire.

They (...) call what I have an invisible illness, but I often wonder if they're really looking. Beyond the science stuff. It doesn't bleed or swell, itch or crack, but I see it, right there on my face. It's like decay, this icky green colour, as if my life were being filmed through a grey filter. I lack light, am an entire surface area that the sun can't touch.

Forest air is the epitome of healthy air. People who want to take a deep breath of fresh air or engage in physical activity in a particularly agreeable atmosphere step out into the forest. There's every reason to do so. The air truly is considerably cleaner under the trees, because the trees act as huge air filters. Their leaves and needles hang in a steady breeze, catching large and small particles as they float by. Per year and square mile this can amount to 20,000 tons of material. Trees trap so much because their canopy presents such a large surface area. In comparison with a meadow of a similar size, the surface area of the forest is hundreds of times larger, mostly because of the size difference between trees and grass. The filtered particles contain not only pollutants such as soot but also pollen and dust blown up from the ground. It is the filtered particles from human activity, however, that are particularly harmful. Acids, toxic hydrocarbons, and nitrogen compounds accumulate in the trees like fat in the filter of an exhaust fan above a kitchen stove. But not only do trees filter materials out of the air, they also pump substances into it. They exchange scent-mails and, of course, pump out phytoncides, both of which I have already mentioned.

I myself have dreamed up a structure intermediate between Dyson spheres and planets. Build a ring 93 million miles in radius - one Earth orbit - around the sun. If we have the mass of Jupiter to work with, and if we make it a thousand miles wide, we get a thickness of about a thousand feet for the base. And it has advantages. The Ringworld will be much sturdier than a Dyson sphere. We can spin it on its axis for gravity. A rotation speed of 770 m/s will give us a gravity of one Earth normal. We wouldn't even need to roof it over. Place walls one thousand miles high at each edge, facing the sun. Very little air will leak over the edges. Lord knows the thing is roomy enough. With three million times the surface area of the Earth, it will be some time before anyone complains of the crowding.

On 20 July 1969, Neil Armstrong and Buzz Aldrin landed on the surface of the moon. In the months leading up to their expedition, the Apollo II astronauts trained in a remote moon-like desert in the western United States. The area is home to several Native American communities, and there is a story – or legend – describing an encounter between the astronauts and one of the locals. One day as they were training, the astronauts came across an old Native American. The man asked them what they were doing there. They replied that they were part of a research expedition that would shortly travel to explore the moon. When the old man heard that, he fell silent for a few moments, and then asked the astronauts if they could do him a favour. ‘What do you want?’ they asked. ‘Well,’ said the old man, ‘the people of my tribe believe that holy spirits live on the moon. I was wondering if you could pass an important message to them from my people.’ ‘What’s the message?’ asked the astronauts. The man uttered something in his tribal language, and then asked the astronauts to repeat it again and again until they had memorised it correctly. ‘What does it mean?’ asked the astronauts. ‘Oh, I cannot tell you. It’s a secret that only our tribe and the moon spirits are allowed to know.’ When they returned to their base, the astronauts searched and searched until they found someone who could speak the tribal language, and asked him to translate the secret message. When they repeated what they had memorised, the translator started to laugh uproariously. When he calmed down, the astronauts asked him what it meant. The man explained that the sentence they had memorised so carefully said, ‘Don’t believe a single word these people are telling you. They have come to steal your lands.

The damage that you have inflicted heals over, and the scarred places left behind have unusual surface areas, roughnesses enough to become the nodes around which wisdom weaves its fibrils.

As the brother put the carving knife aside, he said, "Stuffing?" "Am I breathing?" Phury shoved a spoon into the bird and piled high. "Mashed?" "Do you have gravy?" "Am I breathing?" V cracked a smile. "Roger that. And affirmative on the gravy." When a plate was put in front of him, he glanced up. "No veggies? Not that I'm looking a gift horse in the mouth." "Vegetable matter is a waste of porcelain space." Phury pushed a knife and fork across the butcher block. "Ask yourself, would I sacrifice the surface area of mashed or stuffing for peas?" "I love you.

Of the total surface area of Earth, Britain occupies just 0.0174069 per cent.

Loss creates a greater overall surface area within a person. You expand as a result of it. Though it may very well feel like the opposite.

Sugar has 4000 food-calories per kilogram. One food-calorie is 4184 Joules. Sugar in zero-g will float and the grains will separate, maximizing surface area. In a pure-oxygen environment, 16.7 million joules will be released for every kilogram of sugar used, releasing the explosive force of eight sticks of dynamite. Such is the nature of combustion in pure oxygen.

If Dodger were awake, she’d happily tell him exactly how much of her blood is on the floor. She’d look at the mess around them. She’d calculate the surface area and volume of the liquid as easily as taking a breath, and she’d turn it into a concrete number, something accurate to the quarter ounce. She’d think she was being comforting, even if the number she came up with meant “I’m leaving you.” Even if it meant “there is no coming back from this.” Even if it meant goodbye.

The gut has not only a remarkable system of nerves to gather all this information, but also a huge surface area. That makes it the body’s largest sensory organ. Eyes, ears, nose, or the skin pale by comparison. The information they gather is received by the conscious mind and used to formulate a response to our environment. They can be seen as life’s parking sensors. The gut, by contrast, is a huge matrix, sensing our inner life and working on the subconscious mind.

In separate meetings, Army, Air Force, and Navy commanders each insisted that outer space was their service’s domain. To the Army, the moon was simply “the high ground,” and therefore part of its domain. Air Force generals, claiming that space was “just a little higher up” than the area they already controlled, tried to get Secretary McElroy interested in their plans for “creating a new Aerospace Force.” The admirals and vice admirals of the U.S. Navy argued that “outer space over the oceans” was a natural extension of the “underwater, surface and air regime in which [the Navy] operated” and should therefore be considered the Navy’s domain.

Remember my experiments with the RTG and having a hot bath? Same principle, but I came up with an improvement: submerge the RTG. No heat will be wasted that way. I started with a large rigid sample container (or “plastic box” to people who don’t work at NASA). I ran a tube through the open top and down the inside wall. Then I coiled it in the bottom to make a spiral. I glued it in place like that and sealed the end. Using my smallest drill bit, I put dozens of little holes in the coil. The idea is for the freezing return air from the regulator to pass through the water as a bunch of little bubbles. The increased surface area will get the heat into the air better. Then I got a medium flexible sample container (“Ziploc bag”) and tried to seal the RTG in it. But the RTG has an irregular shape, and I couldn’t get all the air out of the bag. I can’t allow any air in there.

In the United States, though, convenience was everything; it still is. We were plugging anything we could into the internet, at a rate of 127 devices a second. We had bought into Silicon Valley’s promise of a frictionless society. There wasn’t a single area of our lives that wasn’t touched by the web. We could now control our entire lives, economy, and grid via a remote web control. And we had never paused to think that, along the way, we were creating the world’s largest attack surface.

In 1995 Bank of America issued a famous report on sprawl in California. The bank pronounced: 'Urban job centers have decentralized to the suburbs. New housing tracts have moved even deeper into agriculturally and environmentally sensitive areas. Private auto use continues to rise. This acceleration of sprawl has surfaced enormous social, environmental, and economic costs, which until now have been hidden, ignored, or quietly borne by society.

For their surface area, insects weigh very little. A beetle, falling from a high altitude, quickly achieves terminal velocity: air resistance prevents it from falling very fast, and, after alighting on the ground, it will walk away, apparently none the worse for the experience… In contrast, human beings are characteristically maimed or killed by any fall of more than a few dozen feet: because of our size, we weigh too much for our surface area.

His drawings were not originals then, only copies. He must have been doing them as a sort of retirement hobby, he was an incurable amateur and enthusiast; if he'd become hooked (on these rock paintings) he would have combed the area for them, collecting them with his camera, pestering experts by letter whenever he found one; an old man's delusion of usefulness.

People actually occupy around 3 per cent of the earth's land surface. If 1,200 square feet was given to every person in the world, they would still all fit into an area the size of Texas - whether the Texans would object is an altogether different issue!

When sunlight, which contains red, yellow, green, and blue light, shines on a mud puddle with oil on it, the areas that strongly reflect each of those colors overlap and produce all kinds of combinations which our eyes see as different colors...This phenomenon of colors produced by the partial reflection of white light by two surfaces is called iridescence, and can be found in many places...the more you see how strangely Nature behaves, the harder it is to make a model that explains how even the simplest phenomena actually work.

Using freshman level calculus you can show that the one and only shape that has the smallest surface area for an enclosed volume is a perfect sphere. In fact, billions of dollars could be saved annually on packaging materials if all shipping boxes and all packages of food in the supermarket were spheres. For example, the contents of a super-jumbo box of Cheerios would fit easily into a spherical carton with a four-and-half inch radius. But practical matters prevail - nobody wants to chase packaged food down the aisle after it rolls off the shelves.

The earth’s surface measures about 200 million square miles, of which 60 million is land. As late as AD 1400, the vast majority of farmers, along with their plants and animals, clustered together in an area of just 4.25 million square miles – 2 per cent of the planet’s surface.

The CIA resorted to sending high-altitude U-2 spy planes to photograph the area. It was on the second of these missions, in May 1960, that Francis Gary Powers’s aircraft was shot down by a Soviet SA-2 surface-to-air missile, in what became one of the defining events of the Cold War. Although

When a plate was put in front of him, he glanced up. “No veggies? Not that I’m looking a gift horse in the mouth.” “Vegetable matter is a waste of porcelain space.” Phury pushed a knife and fork across the butcher block. “Ask yourself, would I sacrifice the surface area of mashed or stuffing for peas?” “I love you.

Similarly, wings didn’t suddenly appear in all their aerodynamic glory. They developed from organs that served another purpose. According to one theory, insect wings evolved millions of years ago from body protrusions on flightless bugs. Bugs with bumps had a larger surface area than those without bumps, and this enabled them to absorb more sunlight and thus stay warmer. In a slow evolutionary process, these solar heaters grew larger. The same structure that was good for maximum sunlight absorption – lots of surface area, little weight – also, by coincidence, gave the insects a bit of a lift when they skipped and jumped. Those with bigger protrusions could skip and jump farther. Some insects started using the things to glide, and from there it was a small step to wings that could actually propel the bug through the air. Next time a mosquito buzzes in your ear, accuse her of unnatural behaviour. If she were well behaved and content with what God gave her, she’d use her wings only as solar panels.

Heat is lost at the surface, so the more surface area you have relative to volume, the harder you must work to stay warm. That means that little creatures have to produce heat more rapidly than large creatures. They must therefore lead completely different lifestyles. An elephant’s heart beats just thirty times a minute, a human’s sixty, a cow’s between fifty and eighty, but a mouse’s beats six hundred times a minute—ten times a second. Every day, just to survive, the mouse must eat about 50 percent of its own body weight. We humans, by contrast, need to consume only about 2 percent of our body weight to supply our energy requirements. One area where animals are curiously—almost eerily—uniform is with the number of heartbeats they have in a lifetime. Despite the vast differences in heart rates, nearly all animals have about 800 million heartbeats in them if they live an average life. The exception is humans. We pass 800 million heartbeats after twenty-five years, and just keep on going for another fifty years and 1.6 billion heartbeats or so. It is tempting to attribute this exceptional vigor to some innate superiority on our part, but in fact it is only over the last ten or twelve generations that we have deviated from the standard mammalian pattern thanks to improvements in our life expectancy. For most of our history, 800 million beats per lifetime was about the human average, too.

Yet why must it be that men always seek out the depths, the abyss? Why must thought, like a plumb line, concern itself exclusively with vertical descent? Why was it not feasible for thought to change direction and climb vertically up, ever up, towards the surface? Why should the area of the skin, which guarantees a human being’s existence in space, be most despised and left to the tender mercies of the senses? I could not understand the laws governing the motion of thought—the way it was liable to get stuck in unseen chasms whenever it set out to go deep; or, whenever it aimed at the heights, to soar away into boundless and equally invisible heavens, leaving the corporeal form undeservedly neglected.

This is the outer surface of the brain where much of our thinking is done. Unfolded, this surface layer would cover the area of a football field

This “Hawking temperature” of a black hole and its “Hawking radiation” (as they came to be called) were truly radical—perhaps the most radical theoretical physics discovery in the second half of the twentieth century. They opened our eyes to profound connections between general relativity (black holes), thermodynamics (the physics of heat) and quantum physics (the creation of particles where before there were none). For example, they led Stephen to prove that a black hole has entropy, which means that somewhere inside or around the black hole there is enormous randomness. He deduced that the amount of entropy (the logarithm of the hole’s amount of randomness) is proportional to the hole’s surface area. His formula for the entropy is engraved on Stephen’s memorial stone at Gonville and Caius College in Cambridge, where he worked. For the past forty-five years, Stephen and hundreds of other physicists have struggled to understand the precise nature of a black hole’s randomness. It is a question that keeps on generating new insights about the marriage of quantum theory with general relativity—that is, about the ill-understood laws of quantum gravity.

In the subway the trains move so swiftly you can never catch your breath. Outside the grimy window that’s a reflecting surface like a mirror mostly there are the rushing tunnel walls, that slow as the train slows for a station, and the doors open with a pneumatic hiss like the sigh of a great ugly beast, and passengers lurch off, and new passengers lurch on, and I lift my eyes hopeful and yearning Who will be my destiny? Which one of you?

Often people’s identities, that wild inner complexity of soul and color of spirit, become shrunken into their work identities. They become prisoners of their roles. They limit and reduce their lives. They become seduced by the practice of self-absence. They move further and further away from their own lives. They are forced backward into hidden areas on the ledges of their hearts. When you encounter them, you meet only the role. You look for the person, but you never meet him. To practice only the linear external side of your mind is very dangerous. Thus the corporate and work world now recognizes how desperately they need the turbulence, anarchy, and growth possibilities that come from the unpredictable world of the imagination. These are so vital for the passion and force of a person’s life. If you engage only the external side of yourself, and stay on this mechanical surface, you become secretly weary. Gradually, years of this practice make you desperate.

Emerging, as we had, from the dark and gloomy bowels of the earth, the scene before us presented a view of wondrous beauty, and, while doubtless enhanced by contrast, it was nevertheless such an aspect as is seldom given to the eyes, of a Barsoomian of today to view. To me it seemed a little garden spot upon a dying world preserved from an ancient era when Barsoom was young and meteorological conditions were such as to favor the growth of vegetation that has since become extinct over practically the entire area of the planet. In this deep valley, surrounded by lofty cliffs, the atmosphere doubtless was considerably denser than upon the surface of the planet above. The sun's days were reflected by the lofty escarpment, which must also hold the heat during the colder periods of night, and, in addition to this, there was ample water for irrigation which nature might easily have achieved through percolation of the waters of the river through and beneath the top soil of the valley.

An asteroid or comet traveling at cosmic velocities would enter the Earth’s atmosphere at such a speed that the air beneath it couldn’t get out of the way and would be compressed, as in a bicycle pump. As anyone who has used such a pump knows, compressed air grows swiftly hot, and the temperature below it would rise to some 60,000 Kelvin, or ten times the surface temperature of the Sun. In this instant of its arrival in our atmosphere, everything in the meteor’s path—people, houses, factories, cars—would crinkle and vanish like cellophane in a flame. One second after entering the atmosphere, the meteorite would slam into the Earth’s surface, where the people of Manson had a moment before been going about their business. The meteorite itself would vaporize instantly, but the blast would blow out a thousand cubic kilometers of rock, earth, and superheated gases. Every living thing within 150 miles that hadn’t been killed by the heat of entry would now be killed by the blast. Radiating outward at almost the speed of light would be the initial shock wave, sweeping everything before it. For those outside the zone of immediate devastation, the first inkling of catastrophe would be a flash of blinding light—the brightest ever seen by human eyes—followed an instant to a minute or two later by an apocalyptic sight of unimaginable grandeur: a roiling wall of darkness reaching high into the heavens, filling an entire field of view and traveling at thousands of miles an hour. Its approach would be eerily silent since it would be moving far beyond the speed of sound. Anyone in a tall building in Omaha or Des Moines, say, who chanced to look in the right direction would see a bewildering veil of turmoil followed by instantaneous oblivion. Within minutes, over an area stretching from Denver to Detroit and encompassing what had once been Chicago, St. Louis, Kansas City, the Twin Cities—the whole of the Midwest, in short—nearly every standing thing would be flattened or on fire, and nearly every living thing would be dead. People up to a thousand miles away would be knocked off their feet and sliced or clobbered by a blizzard of flying projectiles. Beyond a thousand miles the devastation from the blast would gradually diminish. But that’s just the initial shockwave. No one can do more than guess what the associated damage would be, other than that it would be brisk and global. The impact would almost certainly set off a chain of devastating earthquakes. Volcanoes across the globe would begin to rumble and spew. Tsunamis would rise up and head devastatingly for distant shores. Within an hour, a cloud of blackness would cover the planet, and burning rock and other debris would be pelting down everywhere, setting much of the planet ablaze. It has been estimated that at least a billion and a half people would be dead by the end of the first day. The massive disturbances to the ionosphere would knock out communications systems everywhere, so survivors would have no idea what was happening elsewhere or where to turn. It would hardly matter. As one commentator has put it, fleeing would mean “selecting a slow death over a quick one. The death toll would be very little affected by any plausible relocation effort, since Earth’s ability to support life would be universally diminished.

I’d gone to an outdoor store in Minneapolis called REI about a dozen times over the previous months to purchase a good portion of these items. Seldom was this a straightforward affair. To buy even a water bottle without first thoroughly considering the latest water bottle technology was folly, I quickly learned. There were the pros and cons of various materials to take into account, not to mention the research that had been done regarding design. And this was only the smallest, least complex of the purchases I had to make. The rest of the gear I would need was ever more complex, I realized after consulting with the men and women of REI, who inquired hopefully if they could help me whenever they spotted me before displays of ultralight stoves or strolling among the tents. These employees ranged in age and manner and area of wilderness adventure proclivity, but what they had in common was that every last one of them could talk about gear, with interest and nuance, for a length of time that was so dumbfounding that I was ultimately bedazzled by it. They cared if my sleeping bag had snag-free zipper guards and a face muff that allowed the hood to be cinched snug without obstructing my breathing. They took pleasure in the fact that my water purifier had a pleated glass-fiber element for increased surface area. And their knowledge had a way of rubbing off on me. By the time I made the decision about which backpack to purchase—a top-of-the-line Gregory hybrid external frame that claimed to have the balance and agility of an internal—I felt as if I’d become a backpacking expert.

Should a lady desire fresh air and exercise, she is perfectly safe in taking a turn around her garden. I speak merely of walking into public areas. In such locales, there is the possibility of encountering unsavory characters, wild animals, and even uneven surfaces. I

In the early months of World War II, San Francisco's Fill-more district, or the Western Addition, experienced a visible revolution. On the surface it appeared to be totally peaceful and almost a refutation of the term “revolution.” The Yakamoto Sea Food Market quietly became Sammy's Shoe Shine Parlor and Smoke Shop. Yashigira's Hardware metamorphosed into La Salon de Beauté owned by Miss Clorinda Jackson. The Japanese shops which sold products to Nisei customers were taken over by enterprising Negro businessmen, and in less than a year became permanent homes away from home for the newly arrived Southern Blacks. Where the odors of tempura, raw fish and cha had dominated, the aroma of chitlings, greens and ham hocks now prevailed. The Asian population dwindled before my eyes. I was unable to tell the Japanese from the Chinese and as yet found no real difference in the national origin of such sounds as Ching and Chan or Moto and Kano. As the Japanese disappeared, soundlessly and without protest, the Negroes entered with their loud jukeboxes, their just-released animosities and the relief of escape from Southern bonds. The Japanese area became San Francisco's Harlem in a matter of months. A person unaware of all the factors that make up oppression might have expected sympathy or even support from the Negro newcomers for the dislodged Japanese. Especially in view of the fact that they (the Blacks) had themselves undergone concentration-camp living for centuries in slavery's plantations and later in sharecroppers' cabins. But the sensations of common relationship were missing. The Black newcomer had been recruited on the desiccated farm lands of Georgia and Mississippi by war-plant labor scouts. The chance to live in two-or three-story apartment buildings (which became instant slums), and to earn two-and even three-figured weekly checks, was blinding. For the first time he could think of himself as a Boss, a Spender. He was able to pay other people to work for him, i.e. the dry cleaners, taxi drivers, waitresses, etc. The shipyards and ammunition plants brought to booming life by the war let him know that he was needed and even appreciated. A completely alien yet very pleasant position for him to experience. Who could expect this man to share his new and dizzying importance with concern for a race that he had never known to exist? Another reason for his indifference to the Japanese removal was more subtle but was more profoundly felt. The Japanese were not whitefolks. Their eyes, language and customs belied the white skin and proved to their dark successors that since they didn't have to be feared, neither did they have to be considered. All this was decided unconsciously.

I always felt that someone, a long time ago, organized the affairs of the world into areas that made sense-catagories of stuff that is perfectible, things that fit neatly in perfect bundles. The world of business, for example, is this way-line items, spreadsheets, things that add up, that can be perfected. The legal system-not always perfect, but nonetheless a mind-numbing effort to actually write down all kinds of laws and instructions that cover all aspects of being human, a kind of umbrella code of conduct we should all follow. Perfection is crucial in building an aircraft, a bridge, or a high-speed train. The code and mathematics residing just below the surface of the Internet is also this way. Things are either perfectly right or they will not work. So much of the world we work and live in is based upon being correct, being perfect. But after this someone got through organizing everything just perfectly, he (or probably a she) was left with a bunch of stuff that didn't fit anywhere-things in a shoe box that had to go somewhere. So in desperation this person threw up her arms and said, 'OK! Fine. All the rest of this stuff that isn't perfectible, that doesn't seem to fit anywhere else, will just have to be piled into this last, rather large, tattered box that we can sort of push behind the couch. Maybe later we can come back and figure where it all is supposed to fit in. Let's label the box ART.' The problem was thankfully never fixed, and in time the box overflowed as more and more art piled up. I think the dilemma exists because art, among all the other tidy categories, most closely resembles what it is like to be human. To be alive. It is our nature to be imperfect. The have uncategorized feelings and emotions. To make or do things that don't sometimes necessarily make sense. Art is all just perfectly imperfect. Once the word ART enters the description of what you're up to , it is almost getting a hall pass from perfection. It thankfully releases us from any expectation of perfection. In relation to my own work not being perfect, I just always point to the tattered box behind the couch and mention the word ART, and people seem to understand and let you off the hook about being perfect a go back to their business.

He walked back to St George's-in-the-East, which in his mind he had now reduced to a number of surfaces against which the murderer might have leaned in sorrow, desperation or even, perhaps, joy. For this reason it was worth examining the blackened stones in detail, although he realised that the marks upon them had been deposited by many generations of men and women. It was now a matter of received knowledge in the police force that no human being could rest or move in any area without leaving some trace of his or her identity; but if the walls of the Wapping church were to be analysed by emission spectroscopy, how many partial or residual spectra might be detected? And he had an image of a mob screaming to be set free as he guided his steps towards the tower which rose above the houses cluttered around Red Maiden Lane, Crab Court and Rope Walk.

Feral beauty tangled up and over every surface. Enormous vines and flourishing blooms swathed the area creating a shadowy, organic cathedral. A faint whiff of perfume breezed to her, like jasmine, but sweeter, more delicate—if jasmine could be more delicate without losing its scent entirely. The buzzing of alien insects reminded her of the sticky, summer days of her childhood in the South, and cicadas filled her memory with their incessant mating calls. Here, however, the insects grew louder as it grew darker. It seemed even they understood the dangers of daylight.

Vulnerability feels risky because it involves embracing weakness and imperfection. Image-keeping feels far less risky because we believe it protects our sensitive areas from the judgment of others. For some reason, we believe impressing other women will lead to connection and community, so we expend effort on building an image rather than revealing ourselves. But until we lay down our defenses, until we stop trying to shield our insecurities and shame from the eyes of others, we will not experience the friendship that goes beyond the surface level, the kind we so long for.

Whether one calls slime molds, fungi, and plants “intelligent” depends on one’s point of view. Classical scientific definitions of intelligence use humans as a yardstick by which all other species are measured. According to these anthropocentric definitions, humans are always at the top of the intelligence rankings, followed by animals that look like us (chimpanzees, bonobos, etc.), followed again by other “higher” animals, and onward and downward in a league table—a great chain of intelligence drawn up by the ancient Greeks, which persists one way or another to this day. Because these organisms don’t look like us or outwardly behave like us—or have brains—they have traditionally been allocated a position somewhere at the bottom of the scale. Too often, they are thought of as the inert backdrop to animal life. Yet many are capable of sophisticated behaviors that prompt us to think in new ways about what it means for organisms to “solve problems,” “communicate,” “make decisions,” “learn,” and “remember.” As we do so, some of the vexed hierarchies that underpin modern thought start to soften. As they soften, our ruinous attitudes toward the more-than-human world may start to change. The second field of research that has guided me in this inquiry concerns the way we think about the microscopic organisms—or microbes—that cover every inch of the planet. In the last four decades, new technologies have granted unprecedented access to microbial lives. The outcome? For your community of microbes—your “microbiome”—your body is a planet. Some prefer the temperate forest of your scalp, some the arid plains of your forearm, some the tropical forest of your crotch or armpit. Your gut (which if unfolded would occupy an area of thirty-two square meters), ears, toes, mouth, eyes, skin, and every surface, passage, and cavity you possess teem with bacteria and fungi. You carry around more microbes than your “own” cells. There are more bacteria in your gut than stars in our galaxy. For humans, identifying where one individual stops and another starts is not generally something we

I used to imagine life divided into separate compartments, consisting, for example, of such dual abstractions as pleasure and pain, love and hate, friendship and enmity; and more material classifications like work and play: a profession or calling being, according to that concept—one that seemed, at least on the surface, unequivocally assumed by persons so dissimilar from one another as Widmerpool and Archie Gilbert, something entirely different from “spare time.” That illusion, as such a point of view was, in due course, to appear—was closely related to another belief: that existence fans out indefinitely into new areas of experience, and that almost every additional acquaintance offers some supplementary world with its own hazards and enchantments. As time goes on, of course, these supposedly different worlds, in fact, draw closer, if not to each other, then to some pattern common to all; so that, at last, diversity between them, if in truth existent, seems to be almost imperceptible except in a few crude and exterior ways: unthinkable, as formerly appeared, any single consummation of cause and effect. In other words, nearly all the inhabitants of these outwardly disconnected empires turn out at last to be tenaciously inter-related; love and hate, friendship and enmity, too, becoming themselves much less clearly defined, more often than not showing signs of possessing characteristics that could claim, to say the least, not a little in common; while work and play merge indistinguishably into a complex tissue of pleasure and tedium.

To connect to the holy is to access the deepest, juiciest part of our spirits. Perhaps this is why we set up so many boundaries, protections, and rules around both sex and religion. Both pursuits expose such a large surface area of the self, which can then be either hurt or healed. But when the boundaries, protections, and rules become more important than the sacred thing they are intended to protect, casualties ensue. But no matter how much we strive for purity in our minds, bodies, spirits, or ideologies, purity is not the same as holiness. It's just easier to define what is pure than what is holy, so we pretend they are interchangeable.

the shore was warm and soothing to her, embracing her like a favorite shawl as she sat on the still warm sand and watched the moonlight play on the water’s surface. The incoming and outgoing waves sounded a steady beat—their tiny white crests and white froth glowing in the moonlight. The reflected moonlight lit up the area like dusk.

Even the primary visual areas in the brain show the special organizing function of space. Each patch of cortical real estate is dedicated to a fixed spot in the visual field, and contours in the world are represented as contours across the surface of the brain, at least on a large scale. Time also has a presence in the mind that is more than just any old attribute of an experience. Neuroscientists have found biological clocks ticking in the brains of organisms as simple as fruit flies. And just as we see stuff that is connected in space as an object, we see stuff that is connected in time as a motion, such as a trajectory or gesture, or, in the case of sound, as a melody or stretch of speech.

Sharing our stories, our feelings, it is the area where we are the same that impresses me. The differences are but delightful flourishes on the surface, like different-colored costumes, and I enjoy them. But the basic ways we are human, the basic ways we simply are, stand out to me now. I came to see we are all really one, and I no longer feel alone

Think for a moment about the Agricultural Revolution from the viewpoint of wheat. Ten thousand years ago wheat was just a wild grass, one of many, confined to a small range in the Middle East. Suddenly, within just a few short millennia, it was growing all over the world. According to the basic evolutionary criteria of survival and reproduction, wheat has become one of the most successful plants in the history of the earth. In areas such as the Great Plains of North America, where not a single wheat stalk grew 10,000 years ago, you can today walk for hundreds upon hundreds of miles without encountering any other plant. Worldwide, wheat covers about 870,000 square miles of the globe’s surface, almost ten times the size of Britain. How did this grass turn from insignificant to ubiquitous? Wheat did it by manipulating Homo sapiens to its advantage. This ape had been living a fairly comfortable life hunting and gathering until about 10,000 years ago, but then began to invest more and more effort in cultivating wheat. Within a couple of millennia, humans in many parts of the world were doing little from dawn to dusk other than taking care of wheat plants. It wasn’t easy. Wheat demanded a lot of them. Wheat didn’t like rocks and pebbles, so Sapiens broke their backs clearing fields. Wheat didn’t like sharing its space, water and nutrients with other plants, so men and women laboured long days weeding under the scorching sun. Wheat got sick, so Sapiens had to keep a watch out for worms and blight. Wheat was attacked by rabbits and locust swarms, so the farmers built fences and stood guard over the fields. Wheat was thirsty, so humans dug irrigation canals or lugged heavy buckets from the well to water it. Sapiens even collected animal faeces to nourish the ground in which wheat grew.

For most of history these man-made enclaves remained very small, surrounded by expanses of untamed nature. The earth’s surface measures about 200 million square miles, of which 60 million is land. As late as AD 1400, the vast majority of farmers, along with their plants and animals, clustered together in an area of just 4.25 million square miles – 2 per cent of the planet’s surface.

As late as AD 1400, the vast majority of farmers, along with their plants and animals, clustered together in an area of just 11 million square kilometres – 2 per cent of the planet’s surface.2 Everywhere else was too cold, too hot, too dry, too wet, or otherwise unsuited for cultivation. This minuscule 2 per cent of the earth’s surface constituted the stage on which history unfolded.

The nuggets themselves are pillow-shaped and vaguely striated to echo piratical treasure chests. Now, with a flake-type of cereal, Randy’s strategy would never work. But then, Cap’n Crunch in a flake form would be suicidal madness; it would last about as long, when immersed in milk, as snowflakes sifting down into a deep fryer. No, the cereal engineers at General Mills had to find a shape that would minimize surface area, and, as some sort of compromise between the sphere that is dictated by Euclidean geometry and whatever sunken-treasure-related shapes that the cereal-aestheticians were probably clamoring for, they came up with this hard-to-pin-down striated pillow formation. The important thing, for Randy’s purposes, is that the individual pieces of Cap’n Crunch are, to a very rough approximation, shaped

The big question in cosmology in the early 1960s was did the universe have a beginning? Many scientists were instinctively opposed to the idea, because they felt that a point of creation would be a place where science broke down. One would have to appeal to religion and the hand of God to determine how the universe would start off. This was clearly a fundamental question, and it was just what I needed to complete my PhD thesis. Roger Penrose had shown that once a dying star had contracted to a certain radius, there would inevitably be a singularity, that is a point where space and time came to an end. Surely, I thought, we already knew that nothing could prevent a massive cold star from collapsing under its own gravity until it reached a singularity of infinite density. I realised that similar arguments could be applied to the expansion of the universe. In this case, I could prove there were singularities where space–time had a beginning. A eureka moment came in 1970, a few days after the birth of my daughter, Lucy. While getting into bed one evening, which my disability made a slow process, I realised that I could apply to black holes the casual structure theory I had developed for singularity theorems. If general relativity is correct and the energy density is positive, the surface area of the event horizon—the boundary of a black hole—has the property that it always increases when additional matter or radiation falls into it. Moreover, if two black holes collide and merge to form a single black hole, the area of the event horizon around the resulting black hole is greater than the sum of the areas of the event horizons around the original black holes.

Three laws governing black hole changes were thus found, but it was soon noticed that something unusual was going on. If one merely replaced the words 'surface area' by 'entropy' and 'gravitational field' by 'temperature', then the laws of black hole changes became merely statements of the laws of thermodynamics. The rule that the horizon surface areas can never decrease in physical processes becomes the second law of thermodynamics that the entropy can never decrease; the constancy of the gravitational field around the horizon is the so-called zeroth law of thermodynamics that the temperature must be the same everywhere in a state of thermal equilibrium. The rule linking allowed changes in the defining quantities of the black hole just becomes the first law of thermodynamics, which is more commonly known as the conservation of energy.

The Operation Hardtack II nuclear test series would prove even bigger than Plumbbob, in terms of the number of tests. From September 12 to October 30, 1958, an astonishing thirty-seven nuclear bombs were exploded—from tops of tall towers, in tunnels and shafts, on the surface of the earth, and hanging from balloons. Areas 3, 5, 7, 8, 9, 12, and 15 served as ground zero for the detonations, all within eighteen miles of Area 51.

The strange feature of partial reflection by two surfaces has forced physicists away form making absolute predictions to merely calculating the probability of an event. Quantum electrodynamics provides a method for doing this-drawing little arrows on a piece of paper. The probability of an event is represented by the area of the square of an arrow. For example, an arrow representing a probability of 0.04 (4%) has a length of 0.2.

But at the end of the white board, the edge, where you'll come down with your weight to make it send you off, there are two areas of darkness. Two flat shadows in the broad light. Two vague black ovals. The end of the board has two dirty spots. They are from all the poeple who've gone before you. Your feet as you stand here are tender and dented, hurt by the rough wet surface, and you see that the two dark sports are from people's skin. They are skin abraded from feet by the violence of the disappearance of people with real weight. More people than you could count without losing track. The weight and abrasion of their disappearance leaves little bits of soft tender feet behind, bits and shards and curls of skin that dirty and darken and tan as they lie tiny and smeared in the sun at the end of the board. They pile up and get smeared and mixed together. They darken in two circles.

Of all the plants, trees have the largest surface area covered in leaves. For every square yard of forest, 27 square yards of leaves and needles blanket the crowns. Part of every rainfall is intercepted in the canopy and immediately evaporates again. In addition, each summer, trees use up to 8,500 cubic yards of water per square mile, which they release into the air through transpiration. This water vapor creates new clouds that travel farther inland to release their rain. As the cycle continues, water reaches even the most remote areas. This water pump works so well that the downpours in some large areas of the world, such as the Amazon basin, are almost as heavy thousands of miles inland as they are on the coast. There are a few requirements for the pump to work: from the ocean to the farthest corner, there must be forest. And, most importantly, the coastal forests are the foundations for this system. If they do not exist, the system falls apart. Scientists credit Anastassia Makarieva from Saint Petersburg in Russia for the discovery of these unbelievably important connections. They studied different forests around the world and everywhere the results were the same. It didn't matter if they were studying a rain forest or the Siberian taiga, it was always the trees that were transferring life-giving moisture into land-locked interiors. Researchers also discovered that the whole process breaks down if coastal forests are cleared. It's a bit like if you were using an electrical pump to distribute water and you pulled the intake pipe out of the pond. The fallout is already apparent in Brazil, where the Amazonian rain forest is steadily drying out. Central Europe is within the 400-mile zone and, therefore, close enough to the intake area. Thankfully, there are still forests here, even if they are greatly diminished.

The success of discovering a thermodynamic principle associated with the gravitational field of a black hole has led to a speculation that there might exist some thermodynamic aspect to the gravitational field of the whole Universe. The simplest assumption to make, following the black hole case, would be that it is the surface area of the boundary of the visible universe. As the Universe expands, this boundary increases and the information available to us about the Universe increases. But this does not seem promising. It would appear to tell us only that the Universe must continue expanding forever, for if it were ever to begin to recollapse the entropy would fall and violate the second law of thermodynamics. The universe can expand in all sorts of different ways and still have the increasing area. What we really want is some principle that tells us why the organization of the Universe changes in the way that it does: why it now expands so uniformally and isotropically.

At present, when people become aware of this [common metaphorical] imagery, they tend to think of it as merely a surface dressing of isolated metaphors - as a kind of optional decorative paint that is sometimes added to ideas after they are formed, so as to make them clear to outsiders. But really such symbolism is an integral part of our thought-structure. It does crucial work on all topics, not just in a few supposedly marginal areas such as religion and emotion, where symbols are known to be at home, but throughout our thinking.

As we flew inland from the coast at about 1,200 feet I looked down to see a strange countryside. What I saw wasn't just a western European landscape, but ravaged terrain. The vegetation cover was so sparse a looked a somewhat burgundy tinge- mud oozing from the turf. I'd never seen anything lke it. It was quite surreal. For a few miles along the flight path and stretching towards the French coast on the Channel, as far as the eye could see, were hundreds of thousands of crater rings. There were so many it appeared almost incomprehensible. Yet, there they were, sullen on the surface of this ravaged landscape. We had heard of no heavy artillery attacks in this area, certainly nothing of this concentration of fury. Then it dawned on us quietly that we were flying over the World War 1 battlefields. It was a sobering sight, which filled us with melancholy for the suffering which must have gone on down there. Yet here we were 26 years after that last war ended, going to fight the same enemy. It took some time to come back to reality." Sergeant Dan Hartigan, 1st Canadian Parachute Regiment

We eat spaghetti all' amatriciana, with a sauce of guanciale, which is the pig's" ---he ran his finger down her cheek, briefly, a touch so fleeting she was hardly aware it had happened---"this part of the pig's face. We fry it in olive oil with a little chile, some tomatoes, and of course some grated pecorino romano, hard cheese. Or if you don't want spaghetti, you could have bucatini, or calscioni, or fettuccine, or pappardelle, or tagliolini, or rigatoni, or linguine, or garganelli, or tonnarelli, or fusilli, or conchiglie, or vermicelli, or maccheroni, but---" he held up a warning finger---"each of them demands a different kind of sauce. For example, an oily sauce goes with dried pasta, but a butter sauce goes better with fresh. Take fusilli." He held up a packet to show her. "People say this pasta was designed by Leonardo da Vinci himself. The spiral fins carry the maximum amount of sauce relative to the surface area, you see? But it only works with a thick, heavy sauce that can cling to the grooves. Conchiglie, on the other hand, is like a shell, so it holds a thin, liquid sauce inside it perfectly.

You never asked about your present.' 'I assumed I wasn't getting one from you.' He pushed off the door frame and shut the door behind him. He took up all the air in the room just by standing there. 'Why?' She shrugged. 'I just did.' He pulled a small box from his jacket and set it on the bed between them. 'Surprise.' Cassian swallowed as she approached, the only sign that this meant something to him. Nesta's hands turned sweaty as she picked the box up, examining it. She didn't open it yet, though. 'I am sorry for how I behaved last Solstice. For how awful I was.' He'd gotten her a present then, too. And she hadn't cared, had been so wretched she'd wanted to hurt him for it. For caring. 'I know,' he said thickly. 'I forgave you a long time ago.' She still couldn't look at him, even as he said, 'Open it.' Her hands shook a little as she did, finding a silver ball nestled in the black velvet box. It was the size of a chicken egg, round save for one area that had been flattened so it might be set upon a surface and not roll. 'What is it?' 'Touch the top. Just a tap.' Throwing a puzzled glance at him, she did so. Music exploded into the room. Nesta leaped back, a hand at her chest as he laughed. But- music was playing from the silver orb. And not just any music, but the waltzes from the ball the other night, pure and free of any crowd chattering, as if she were sitting in a theatre to hear them. 'This isn't the Veritas orb,' she managed to say as the waltz poured out of the ball, so clear and perfect her blood sang again. 'No, it's a Symphonia, a rare device from Helion's court. It can trap music within itself, and play it back for you. It was originally invented to help compose music, but it never caught on, for some reason.' 'How did you get the crowd noise out when you trapped the sound the other night?' she marvelled. His cheeks stained with colour. 'I went back the next day. Asked the musicians at the Hewn City to play it all again for me, plus some of their favourites.' He nodded to the ball. 'And then I went to some of your favourite taverns and found those musicians and had them play...' He trailed off at her bowed head. The tears she couldn't stop. She didn't try to fight them as the music poured into the room. He had done all of this for her. Had found a way for her to have music- always. 'Nesta,' he breathed.

My hands were paralyzed, one wrapped around the handle of the Hyena’s sword, spikes sticking through the flesh and out the back of hand, thumb and fingers, too painful for me to let go of it. The other hand was tangled by the locket and the cord that surrounded the imp’s book, fingers bent back out of position. When I moved, it had been a jerky, frustrated movement, the length of the sword, the pain, and the weight of the sword and book all frustrating my attempts to interact with the world. My arms were cracked open like a hard plastic doll, and all that was within were feathers of mixed, dull colors, sticking to one another. I couldn’t move fast enough to catch up to anyone. I was too tired, too gaunt, an old man in a young-looking body, and the objects bound to my hands were too awkward to allow me to open doors easily or even walk through a crowded area without banging them on something. I couldn’t close my eyes, because something black and monstrous slithered beneath the surface every time I did. When I breathed, it was like I was having the heart attack again. The air I spent was air that I couldn’t replenish by any means. I was deflating, losing substance. There was nothing to do but stand there, too tired to move, arms spread like I was crucified, or a bird in mid-flight, staring at Rose and her gathered summonings, with Pauz perched on her shoulder. I somehow knew that words would cost me more of that vital substance than I could afford to spare. I knew, too, that nobody would listen. I stared until my eyes watered, because the idea of blinking was too terrifying.. The water in my eyes became welling moisture, and the resulting tear that fell from my right eye was black and heavy. I could feel the tendrils and tiny clawed feet reaching out from the tear, rasping against my cheekbone.

Wall and Melzack showed how a chronic injury not only makes the cells in the pain system fire more easily but can also cause our pain maps to enlarge their “receptive field” (the area of the body’s surface that they map for), so that we begin to feel pain over a larger area of our body’s surface. This was happening to Moskowitz, whose neck pain was spreading to both sides of his neck. Wall and Melzack also showed that as maps enlarge, pain signals in one map can “spill” into adjacent pain maps. Then we may develop referred pain, when we are hurt in one body part but feel the pain in another, some distance away.

Is what I am not saying, young LaMont Chu, is why you cease to seem to give total effort of self since you begin with the clipping pictures of great professional figures for your adhesive tape and walls. No? Because, privileged gentlemen and boys I am saying, is always something that is too. Cold. Hot. Wet and dry. Very bright sun and you see the purple dots. Very bright hot and you have no salt. Outside is wind, the insects which like the sweat. Inside is smell of heaters, echo, being jammed in together, tarp is overclose to baseline, not enough of room, bells inside clubs which ring the hour loudly to distract, clunk of machines vomiting sweet cola for coins. Inside roof too low for the lob. Bad lighting, so. Or outside: the bad surface. Oh no look no: crabgrass in cracks along baseline. Who could give the total, with crabgrass. Look here is low net high net. Opponent’s relatives heckle, opponent cheats, linesman in semifinal is impaired or cheats. You hurt. You have the injury. Bad knee and back. Hurt groin area from not stretching as asked. Aches of elbow. Eyelash in eye. The throat is sore. A too pretty girl in audience, watching. Who could play like this? Big crowd overwhelming or too small to inspire. Always something.’ [p.458]

Prior to these results, physicists had reasoned that since the Planck length (10^33) centimeters) was apparently the shortest length for which the notion of "distance" continues to have meaning, the smallest meaningful volume would be a tiny cube whose edges were each one Planck length long (a volume of 10^-99) cubic centimeters). A reasonable conjecture, widely believed, was that irrespective of future technological breakthroughs, the smallest possible volume could store no more than the smallest unit of information-one bit. And so the expectation was that a region of space would max out its information storage capacity when the number of bits it contained equaled the number of Planck cubes that could fit inside it. That Hawking's result involved the Planck length was therefore not surprising. The surprise was that the black hole's storehouse of hidden information was determined by the number of Planck-sized squares covering its surface and not by the number of Planck-sized cubes filling its volume. This was the first hint of holography-information storage capacity determined by the area of a bounding surface and not by the volume interior to that surface . Through twists and turns across three subsequent decades, this hint would evolve into a dramatic new way of thinking about the laws of physics.

There are many examples where species share common plastic traits. What appears to be convergence may just be the plastic response of the organism to its environment. Examples include the following: Limbs that protrude from an animal’s body have more surface area per unit mass than the rest of the body. In cold weather the animal loses more heat per unit mass from these limbs than from other parts of the body. In many species the tails and legs are shorter for those living in colder climates and larger for those in warmer climates. Gulls’ wings are shorter in cold climates than in warm. Hares and foxes also have shorter ears in cold climates than in warm. Eskimos have shorter arms and legs than do people living in warmer climates. . . . Jodan’s rule: Many species of fish tend to have more vertebrae when they live in cold water than do the same species living in warm water. These differences have been shown to depend on the temperature at which the fish have been reared. What these rules show is not convergence. They show that different species adopt the same anatomical strategies when they have to cope with the same environmental conditions. We have seen that these strategies cannot come from random mutations. It is much more reasonable to say they come from environmental cues acting on the genetic program.

A.N. Kolmogorov and Yasha Sinai had worked out some illuminating mathematics for the way a system's "entropy per unit time" applies to the geometric pictures of surfaces stretching and folding in phase space. The conceptual core of the technique was a matter of drawing some arbitrarily small box around some set of initial conditions, as one might draw a small square on the side of a balloon, then calculating the effect of various expressions or twists on the box. It might stretch in one direction, for example, while remaining narrow in the other. The change in area corresponded to an introduction of uncertainty about the system's past, a gain or loss of information.

One aspect of the civil-rights struggle that receives little attention is the contribution it makes to the whole society. The Negro in winning rights for himself produces substantial benefits for the nation. Just as a doctor will occasionally reopen a wound, because a dangerous infection hovers beneath the half-healed surface, the revolution for human rights is opening up unhealthy areas in American life and permitting a new and wholesome healing to take place. Eventually the civil-rights movement will have contributed infinitely more to the nation than the eradication of racial injustice. It will have enlarged the concept of brotherhood to a vision of total interrelatedness.

A recent analysis of satellite imagery, for example, has shown that the total "constructed" area in the continental United States is now equal to the size of the state of Ohio. Never has so much of the Earth's surface been covered by materials designed to be impervious (concrete, pavement, buildings). These surfaces not only decrease the proportion of precipitation that soaks into the substrate to become groundwater, but also change the reflectivity, biological diversity, and carbon storage capacity of the land. Not all of these changes are necessarily bad, but they will interact in subtle and unpredictable ways with other environmental changes, both natural and human-induced.

Then, in 1974, Stephen Hawking made a dramatic discovery. He decided to examine for the forst time what occurs when one applies the notions of quantum mechanics to black holes. What he discovered was that black holes are not completely black. When quantum mechanics is included in the discussion of their properties, it is possible for energy to escape from the surface of the black hole and be recorded by an outside observer. The variation in the strength of the gravitational field near the horizon surface is strong enough to create pairs of particles and antiparticles spontaneously. The energy necessary to do this is extracted from the source of the gravitational field, and as the process continues, so the mass of the black hole ebbs away. If one waits long enough, it should disappear completely unless some unknown physics intervenes in the final stages. Such a discovery was exciting enough, but its most satisfying aspect was the fact that the particles radiated away from the surface of the black hole were found to have all the characteristics of heat radiation, with a temperature precisely equal to the gravitational field at the horizon and an entropy given by its surface area, just as the analogy had suggested. Black holes did possess a non-zero temperature and obeyed the laws of thermodynamics, but only when quantum mechanics was included in their description.

The Pacific, greatest of oceans, has an area exceeding that of all dry land on the planet. Herman Melville called it "the tide-beating heart of earth." Covering more than a third of the planet's surface--as much as the Atlantic, Indian, and Arctic oceans combined--it's the largest geographical feature in the world. Its awesome 165,384,000 square km (up to 16,000 km wide and 11,000 km long) have an average depth of around 4,000 meters. Half the world's liquid water is stored here. You could drop the entire dry landmass of our planet into the Pacific and still have room for another continent the size of Asia. One theory claims the moon may have been flung from the Pacific while the world was still young.

There was another inspiring moment: a rough, choppy, moonlit night on the water, and the Dreadnaught's manager looked out the window suddenly to spy thousands of tiny baitfish breaking the surface, rushing frantically toward shore. He knew what that meant, as did everyone else in town with a boat, a gaff and a loaf of Wonder bread to use as bait: the stripers were running! Thousands of the highly prized, relatively expensive striped bass were, in a rare feeding frenzy, suddenly there for the taking. You had literally only to throw bread on the water, bash the tasty fish on the head with a gaff and then haul them in. They were taking them by the hundreds of pounds. Every restaurant in town was loading up on them, their parking lots, like ours, suddenly a Coleman-lit staging area for scaling, gutting and wrapping operations. The Dreadnaught lot, like every other lot in town, was suddenly filled with gore-covered cooks and dishwashers, laboring under flickering gaslamps and naked bulbs to clean, wrap and freeze the valuable white meat. We worked for hours with our knives, our hair sparkling with snowflake-like fish scales, scraping, tearing, filleting. At the end of the night's work, I took home a 35-pound monster, still twisted with rigor. My room-mates were smoking weed when I got back to our little place on the beach and, as often happens on such occasions, were hungry. We had only the bass, some butter and a lemon to work with, but we cooked that sucker up under the tiny home broiler and served it on aluminum foil, tearing at it with our fingers. It was a bright, moonlit sky now, a mean high tide was lapping at the edges of our house, and as the windows began to shake in their frames, a smell of white spindrift and salt saturated the air as we ate. It was the freshest piece of fish I'd ever eaten, and I don't know if it was due to the dramatic quality the weather was beginning to take on, but it hit me right in the brainpan, a meal that made me feel better about things, made me better for eating it, somehow even smarter, somehow . . . It was a protein rush to the cortex, a clean, three-ingredient ingredient high, eaten with the hands. Could anything be better than that?

THE SEVEN KEY CHARACTERIZATION VARIABLES Think of these as realms, as areas of potential character illumination. Here they are, in no particular order: Surface affectations and personality—What the world sees and perceives about a character, including quirks, ticks, habits, and visual presentation. Backstory—All that happened in the character’s life before the story begins that conspires to make him who he is now. Character arc—How the character learns lessons and grows (changes) over the course of the story, how she evolves and conquers her most confounding issues. Inner demons and conflicts—The nature of the issues that hold a character back and define his outlook, beliefs, decisions, and actions. Fear of meeting new people, for example, is a demon that definitely compromises one’s life experience. Worldview—An adopted belief system and moral compass; the manifested outcome of backstory and inner demons. Goals and motivations—What drives a character’s decisions and actions, and the belief that the benefits of those decisions and actions outweigh any costs or compromises. Decisions, actions, and behaviors—The ultimate decisions and actions that are the sum of all of the above. Everything about your characters depends on this final variable, and the degree to which the character’s decisions, actions, and behaviors have meaning and impact depends on how well you’ve manipulated the first six variables before, during, and after the moment of decision or action.

Because a lake is conceived as having only two primary dimensions, you can't swim inside the lake, though that would seem to make geometric sense. Lederer asks why we say that something can be underwater or underground even though it's surrounded by, not beneath, the water or the ground. It's because water and ground are conceived as 2-D surfaces, not 3-D volumes, geologically improbable though that is. The dimensionality of an object is also the aspect of its geometry that modifiers "see" when they combine with it in a phrase. A big CD, for example, has to have an above-average diameter, not an above-standard thickness (that could only be a thick CD), and a big lake has to be one with an unusually large area, regardless of its depth; it can't be a few yards wide and a mile deep.

Thus, when the eye-cups (the future retina), which grow out of the brain at the end of two stalks (the future optic nerves), make physical contact with the surface, the skin over the contact area folds into the concave cups and differentiates into transparent lenses (see arrows on the right of the diagram). The eye-cup induces the skin to form a lens, and the lens in its turn induces adjacent tissues to form a transparent horny membrane, the cornea. Moreover, if an eye-cup is transplanted under the skin on the belly of a frog embryo, the skin over it will obligingly differentiate into a lens. We may regard this obligingness or 'docility' of embryonic tissue, its readiness to differentiate into the kind of organ best suited to the tissue's position in the growing organism, as a manifestation of the integrative tendency, of the part's subordination to the interests of the whole.

Two observations take us across the finish line. The Second Law ensures that entropy increases throughout the entire process, and so the information hidden within the hard drives, Kindles, old-fashioned paper books, and everything else you packed into the region is less than that hidden in the black hole. From the results of Bekenstein and Hawking, we know that the black hole's hidden information content is given by the area of its event horizon. Moreover, because you were careful not to overspill the original region of space, the black hole's event horizon coincides with the region's boundary, so the black hole's entropy equals the area of this surrounding surface. We thus learn an important lesson. The amount of information contained within a region of space, stored in any objects of any design, is always less than the area of the surface that surrounds the region (measured in square Planck units). This is the conclusion we've been chasing. Notice that although black holes are central to the reasoning, the analysis applies to any region of space, whether or not a black hole is actually present. If you max out a region's storage capacity, you'll create a black hole, but as long as you stay under the limit, no black hole will form. I hasten to add that in any practical sense, the information storage limit is of no concern. Compared with today's rudimentary storage devices, the potential storage capacity on the surface of a spatial region is humongous. A stack of five off-the-shelf terabyte hard drives fits comfortable within a sphere of radius 50 centimeters, whose surface is covered by about 10^70 Planck cells. The surface's storage capacity is thus about 10^70 bits, which is about a billion, trillion, trillion, trillion, trillion terabytes, and so enormously exceeds anything you can buy. No one in Silicon Valley cares much about these theoretical constraints. Yet as a guide to how the universe works, the storage limitations are telling. Think of any region of space, such as the room in which I'm writing or the one in which you're reading. Take a Wheelerian perspective and imagine that whatever happens in the region amounts to information processing-information regarding how things are right now is transformed by the laws of physics into information regarding how they will be in a second or a minute or an hour. Since the physical processes we witness, as well as those by which we're governed, seemingly take place within the region, it's natural to expect that the information those processes carry is also found within the region. But the results just derived suggest an alternative view. For black holes, we found that the link between information and surface area goes beyond mere numerical accounting; there's a concrete sense in which information is stored on their surfaces. Susskind and 'tHooft stressed that the lesson should be general: since the information required to describe physical phenomena within any given region of space can be fully encoded by data on a surface that surrounds the region, then there's reason to think that the surface is where the fundamental physical processes actually happen. Our familiar three-dimensional reality, these bold thinkers suggested, would then be likened to a holographic projection of those distant two-dimensional physical processes. If this line of reasoning is correct, then there are physical processes taking place on some distant surface that, much like a puppeteer pulls strings, are fully linked to the processes taking place in my fingers, arms, and brain as I type these words at my desk. Our experiences here, and that distant reality there, would form the most interlocked of parallel worlds. Phenomena in the two-I'll call them Holographic Parallel Universes-would be so fully joined that their respective evolutions would be as connected as me and my shadow.

If the weakness of mainstream fiction is its deliberate smallness, the weakness of sf is its puffed-up size, its gauzy immensities. SF often pays so much attention to cosmic ideas that the story's surface is vague. Too much sf suffers from a lack of tangible reality. Muzzy settings, generic characters concocted merely for the sake of the idea, improbable action plots tidily wrapped up at the end. Too much preaching, not enough concrete, credible detail. An sf writer can get published without mastering certain things that most mainstream writers can’t evade: evocative prose style, naturalistic dialogue, attention to detail. Refraining from editorializing, over-explaining, or pat resolutions. To us, the contents of The Best American Short Stories seem paltry and timebound. To them, the contents of Asimov’s are overblown and underrealized. It’s no wonder that sf never makes the Ravenel collection. SF is habitually strong in areas considered unessential to good mainstream fiction, and weak in those areas that are considered essential. It doesn't matter that to the sf reader most contemporary fiction is so interested in "how things really are" in tight focus that it missed "how things really are" in the big picture. SF’s different standards make it invisible to mainstream readers, not in the literal way of H.G. Wells's invisible man, but in the cultural way of Ralph Ellison's. It's not that they can’t see us, it's that they don't know what to make of what they see. What they don't know about sf, and worse still, what they think they do know, make it impossible for them to appreciate our virtues. We are like a Harlem poet attempting to find a seat at the Algonquin round table in 1925. Our clothes are outlandish . Our accent is uncouth. The subjects we are interested in are uninteresting or incomprehensible. Our history and culture are unknown. Our reasons for being there are inadmissible. The result is embarrassment, condescension, or silence.

In the end, what is most satisfying about the picture of space given by loop quantum gravity is that it is completely relational. The spin networks do not live in space; their structure generates space. And they are nothing but a structure of relations, governed by how the edges are tied together at the nodes. Also coded in are rules about how the edges may knot and link with one another. It is also very satisfying that there is a complete correspondence between the classical and quantum pictures of geometry. In classical geometry the volumes of regions and the areas of the surfaces depend on the values of gravitational fields. They are coded in certain complicated collections of mathematical functions, known collectively as the metric tensor. On the other hand, in the quantum picture the geometry is coded in the choice of a spin network. These spin networks correspond to the classical description in that, given any classical geometry, one can find a spin network which describes, to some level of approximation, the same geometry (Figure 27).

The Dark Depths of the Seas And Internal Waves Or [the unbelievers' state] are like the darkness of a fathomless sea which is covered by waves above which are waves above which are clouds, layers of darkness, one upon the other. If he puts out his hand, he can scarcely see it. Those Allah gives no light to, they have no light. (Qur'an, 24:40) In deep seas and oceans, the darkness is found at a depth of 200 meters (660 feet) and deeper. At this depth, there is almost no light, and below a depth of 1,000 meters (3,280 feet) there is no light at all.65 Today, we know about the general formation of the sea, the characteristics of the living things in it, its salinity, as well as the amount of water it contains, and its surface area and depth. Submarines and special equipment, developed with modern technology, have enabled scientists to obtain such information. Human beings are not able to dive to a depth of more than 70 meters (230 feet) without the aid of special equipment. They cannot survive unaided in the dark depths of the oceans, such as at a depth of 200 meters (660 feet). For these reasons, scientists have only recently been able to discover detailed information about the seas. However, that the depth of the sea is dark was revealed in the Qur'an 1,400 years ago. It is certainly one of the miracles of the Qur'an that such information was given at a time where no equipment to enable man to dive into the depths of the oceans was available. In addition, the statement in Surat an-Nur 40 "…like the darkness of a fathomless sea which is covered by waves above which are waves above which are clouds…" draws our attention to another miracle of the Qur'an. Scientists have only recently discovered that there are sub-surface waves, which "occur on density interfaces between layers of different densities." These internal waves cover the deep waters of seas and oceans because deep water has a higher density than the water above it. Internal waves act like surface waves. They can break, just like surface waves. Internal waves cannot be discerned by the human eye, but they can be detected by studying temperature or salinity changes at a given location.66 The statements in the Qur'an run parallel precisely the above explanation. Certainly, this fact, which scientists has discovered very recently, shows once again that the Qur'an is the word of Allah.

The crust [of the earth] is very thin. Estimates of its thickness range from a minimum of about twenty to a maximum of about forty miles. The crust is made of comparatively rigid, crystalline rock, but it is fractured in many places, and does not have great strength. Immediately under the crust is a layer that is thought to be extremely weak, because it is, presumably, too hot to crystallize. Moreover, it is thought that pressure at that depth renders the rock extremely plastic, so that it will yield easily to pressures. The rock at that depth is supposed to have high viscosity; that is, it is fluid but very stiff, as tar may be. It is known that a viscous material will yield easily to a comparatively slight pressure exerted over a long period of time, even though it may act as a solid when subjected to a sudden pressure, such as an earthquake wave. If a gentle push is exerted horizontally on the earth's crust, to shove it in a given direction, and if the push is maintained steadily for a long time, it is highly probable that the crust willl be displaced over this plastic and viscous lower layer. The crust, in this case, will move as a single unit, the whole crust at the same time. This idea has nothing whatever to do with the much discussed theory of drifting continents, according to which the continents drifted separately, in different directions. [...] Let us visualize briefly the consequences of a displacement of the whole crustal shell of the earth. First, there will be the changes in latitude. Places on the earth's surface will change their distances from the equator. Some will be shifted nearer the equator, and others farther away. Points on opposite sides of the earth will move in opposite directions. For example, if New York should be moved 2,000 miles south, the Indian Ocean, diametrically opposite, would have to be shifted 2,000 miles north. [...] Naturally, climatic changes will be more or less proportionate to changes in latitude, and, because areas on opposite sides of the globe will be moving in opposite directions, some areas will be getting colder while others get hotter; some will be undergoing radical changes of climate, some mild changes of climate, and some no changes at all. Along with the climatic changes, there will be many other consequences of a displacement of the crust. Because of the slight flattening of the earth, there will be stretching and compressional effects to crack and fold the crust, possibly contributing to the formation of mountain ranges. there will be changes in sea level, and many other consequences.

Flynn lived in a shiny glass apartment tower on the water in Melbourne. The building looked like hundreds of mirrors reflecting the bright blue sky. He lived at the top of the high-rise. Kope and I stepped off the elevator and looked down the hall at Flynn’s door. We’d been silent. Nodding to each other, we sent our hearing into the apartment. With a quiet gasp, I yanked my auditory sense back to normal. Flynn was busy with company at the moment. Very busy. Kope made a low sound and closed his eyes, shaking his head as if to clear away the sounds he’d heard. My face heated and I shifted from foot to foot, fighting back the nervous smile that always wanted to surface at inappropriate times. I found a small sitting area around the corner with glass walls overlooking the city. We sat, taking in the view. When my stupid urge to smile finally settled, I braved another look at Kope and pointed to myself, using my new, limited sign-language skills to tell him I’d listen. Given the new information about his inclination for lust, it was only fair. I quickly looked away, embarrassed by the crassness of the situation. I wasn’t going to listen the whole time. I’d just pop in for a quick check. Ten minutes passed. Still busy. Half an hour passed. Busy. Forty-five minutes passed. I shook my head to let Kope know they were still at it. He fidgeted and paced, out of his normal, calm comfort zone. An hour and ten minutes passed, and I took a turn at stretching my legs. I was getting hungry. I thought we’d be through with our talk by this time. We could interrupt Flynn, but I didn’t want him to freak out in front of somebody. We needed his guest to leave so we could talk alone. At the hour and a half mark, Kope checked his watch and looked at me. I sent my hearing into the room. Oh, they weren’t in the bedroom anymore. Finally! I wiggled my hearing around until it hit the sound of running water. A shower. This was a good sign. But wait . . . nope. I shook my head, eyes wide. Was this normal? Kope did something uncharacteristic then. He grinned, giving a little huff through his nose. This elicited a small giggle from me and I pressed both hands over my mouth. It was too late, though. At this point, I wouldn’t be able to stop myself. I could feel the crazy, unfortunate amusement rising. I jumped up and ran as spritely as I could to the stairwell with Kope on my heels. We sprinted down several flights before I fell back against the wall, laughter bubbling out. It went on and on, only getting worse when Kope joined in with his deep chuckling, a joyful rumble.

Unchopping a Tree. Start with the leaves, the small twigs, and the nests that have been shaken, ripped, or broken off by the fall; these must be gathered and attached once again to their respective places. It is not arduous work, unless major limbs have been smashed or mutilated. If the fall was carefully and correctly planned, the chances of anything of the kind happening will have been reduced. Again, much depends upon the size, age, shape, and species of the tree. Still, you will be lucky if you can get through this stages without having to use machinery. Even in the best of circumstances it is a labor that will make you wish often that you had won the favor of the universe of ants, the empire of mice, or at least a local tribe of squirrels, and could enlist their labors and their talents. But no, they leave you to it. They have learned, with time. This is men's work. It goes without saying that if the tree was hollow in whole or in part, and contained old nests of bird or mammal or insect, or hoards of nuts or such structures as wasps or bees build for their survival, the contents will have to repaired where necessary, and reassembled, insofar as possible, in their original order, including the shells of nuts already opened. With spider's webs you must simply do the best you can. We do not have the spider's weaving equipment, nor any substitute for the leaf's living bond with its point of attachment and nourishment. It is even harder to simulate the latter when the leaves have once become dry — as they are bound to do, for this is not the labor of a moment. Also it hardly needs saying that this the time fro repairing any neighboring trees or bushes or other growth that might have been damaged by the fall. The same rules apply. Where neighboring trees were of the same species it is difficult not to waste time conveying a detached leaf back to the wrong tree. Practice, practice. Put your hope in that. Now the tackle must be put into place, or the scaffolding, depending on the surroundings and the dimension of the tree. It is ticklish work. Almost always it involves, in itself, further damage to the area, which will have to be corrected later. But, as you've heard, it can't be helped. And care now is likely to save you considerable trouble later. Be careful to grind nothing into the ground. At last the time comes for the erecting of the trunk. By now it will scarcely be necessary to remind you of the delicacy of this huge skeleton. Every motion of the tackle, every slightly upward heave of the trunk, the branches, their elaborately reassembled panoply of leaves (now dead) will draw from you an involuntary gasp. You will watch for a lead or a twig to be snapped off yet again. You will listen for the nuts to shift in the hollow limb and you will hear whether they are indeed falling into place or are spilling in disorder — in which case, or in the event of anything else of the kind — operations will have to cease, of course, while you correct the matter. The raising itself is no small enterprise, from the moment when the chains tighten around the old bandages until the boles hands vertical above the stump, splinter above splinter. How the final straightening of the splinters themselves can take place (the preliminary work is best done while the wood is still green and soft, but at times when the splinters are not badly twisted most of the straightening is left until now, when the torn ends are face to face with each other). When the splinters are perfectly complementary the appropriate fixative is applied. Again we have no duplicate of the original substance. Ours is extremely strong, but it is rigid. It is limited to surfaces, and there is no play in it. However the core is not the part of the trunk that conducted life from the roots up to the branches and back again. It was relatively inert. The fixative for this part is not the same as the one for the outer layers and the bark, and if either of these is involved

We know nothing about how those earliest known surface glazes themselves were developed. Nevertheless, we can infer the methods of prehistoric invention by watching technologically “primitive” people today, such as the New Guineans with whom I work. I already mentioned their knowledge of hundreds of local plant and animal species and each species’ edibility, medical value, and other uses. New Guineans told me similarly about dozens of rock types in their environment and each type’s hardness, color, behavior when struck or flaked, and uses. All of that knowledge is acquired by observation and by trial and error. I see that process of “invention” going on whenever I take New Guineans to work with me in an area away from their homes. They constantly pick up unfamiliar things in the forest, tinker with them, and occasionally find them useful enough to bring home. I see the same process when I am abandoning a campsite, and local people come to scavenge what is left. They play with my discarded objects and try to figure out whether they might be useful in New Guinea society. Discarded tin cans are easy: they end up reused as containers. Other objects are tested for purposes very different from the one for which they were manufactured. How would that yellow number 2 pencil look as an ornament, inserted through a pierced ear-lobe or nasal septum? Is that piece of broken glass sufficiently sharp and strong to be useful as a knife? Eureka!

I USED to imagine life divided into separate compartments, consisting, for example, of such dual abstractions as pleasure and pain, love and hate, friendship and enmity; and more material classifications like work and play: a profession or calling being, according to that concept—one that seemed, at least on the surface, unequivocally assumed by persons so dissimilar from one another as Widmerpool and Archie Gilbert—something entirely different from ‘spare time’. That illusion—as such a point of view was, in due course, to appear—was closely related to another belief: that existence fans out indefinitely into new areas of experience, and that almost every additional acquaintance offers some supplementary world with its own hazards and enchantments. As time goes on, of course, these supposedly different worlds, in fact, draw closer, if not to each other, then to some pattern common to all; so that, at last, diversity between them, if in truth existent, seems to be almost imperceptible except in a few crude and exterior ways: unthinkable as formerly appeared any single consummation of cause and effect. In other words, nearly all the inhabitants of these outwardly disconnected empires turn out at last to be tenaciously interrelated; love and hate, friendship and enmity, too, becoming themselves much less clearly defined, more often than not showing signs of possessing characteristics that could claim, to say the least, not a little in common; while work and play merge indistinguishably into a complex tissue of pleasure and tedium.

Treating Abuse Today (Tat), 3(4), pp. 26-33 Freyd: I see what you're saying but people in psychology don't have a uniform agreement on this issue of the depth of -- I guess the term that was used at the conference was -- "robust repression." TAT: Well, Pamela, there's a whole lot of evidence that people dissociate traumatic things. What's interesting to me is how the concept of "dissociation" is side-stepped in favor of "repression." I don't think it's as much about repression as it is about traumatic amnesia and dissociation. That has been documented in a variety of trauma survivors. Army psychiatrists in the Second World War, for instance, documented that following battles, many soldiers had amnesia for the battles. Often, the memories wouldn't break through until much later when they were in psychotherapy. Freyd: But I think I mentioned Dr. Loren Pankratz. He is a psychologist who was studying veterans for post-traumatic stress in a Veterans Administration Hospital in Portland. They found some people who were admitted to Veteran's hospitals for postrraumatic stress in Vietnam who didn't serve in Vietnam. They found at least one patient who was being treated who wasn't even a veteran. Without external validation, we just can't know -- TAT: -- Well, we have external validation in some of our cases. Freyd: In this field you're going to find people who have all levels of belief, understanding, experience with the area of repression. As I said before it's not an area in which there's any kind of uniform agreement in the field. The full notion of repression has a meaning within a psychoanalytic framework and it's got a meaning to people in everyday use and everyday language. What there is evidence for is that any kind of memory is reconstructed and reinterpreted. It has not been shown to be anything else. Memories are reconstructed and reinterpreted from fragments. Some memories are true and some memories are confabulated and some are downright false. TAT: It is certainly possible for in offender to dissociate a memory. It's possible that some of the people who call you could have done or witnessed some of the things they've been accused of -- maybe in an alcoholic black-out or in a dissociative state -- and truly not remember. I think that's very possible. Freyd: I would say that virtually anything is possible. But when the stories include murdering babies and breeding babies and some of the rather bizarre things that come up, it's mighty puzzling. TAT: I've treated adults with dissociative disorders who were both victimized and victimizers. I've seen previously repressed memories of my clients' earlier sexual offenses coming back to them in therapy. You guys seem to be saying, be skeptical if the person claims to have forgotten previously, especially if it is about something horrible. Should we be equally skeptical if someone says "I'm remembering that I perpetrated and I didn't remember before. It's been repressed for years and now it's surfacing because of therapy." I ask you, should we have the same degree of skepticism for this type of delayed-memory that you have for the other kind? Freyd: Does that happen? TAT: Oh, yes. A lot.

On 20 July 1969, Neil Armstrong and Buzz Aldrin landed on the surface of the moon. In the months leading up to their expedition, the Apollo II astronauts trained in a remote moon-like desert in the western United States. The area is home to several Native American communities, and there is a story –or legend –describing an encounter between the astronauts and one of the locals. One day as they were training, the astronauts came across an old Native American. The man asked them what they were doing there. They replied that they were part of a research expedition that would shortly travel to explore the moon. When the old man heard that, he fell silent for a few moments, and then asked the astronauts if they could do him a favour. ‘What do you want?’ they asked. ‘Well,’ said the old man, ‘the people of my tribe believe that holy spirits live on the moon. I was wondering if you could pass an important message to them from my people.’ ‘What’s the message?’ asked the astronauts. The man uttered something in his tribal language, and then asked the astronauts to repeat it again and again until they had memorised it correctly. ‘What does it mean?’ asked the astronauts. ‘Oh, I cannot tell you. It’s a secret that only our tribe and the moon spirits are allowed to know.’ When they returned to their base, the astronauts searched and searched until they found someone who could speak the tribal language, and asked him to translate the secret message. When they repeated what they had memorised, the translator started to laugh uproariously. When he calmed down, the astronauts asked him what it meant. The man explained that the sentence they had memorised so carefully said, ‘Don’t believe a single word these people are telling you. They have come to steal your lands.

Think for a moment about the Agricultural Revolution from the viewpoint of wheat. Ten thousand years ago wheat was just a wild grass, one of many, confined to a small range in the Middle East. Suddenly, within just a few short millennia, it was growing all over the world. According to the basic evolutionary criteria of survival and reproduction, wheat has become one of the most successful plants in the history of the earth. In areas such as the Great Plains of North America, where not a single wheat stalk grew 10,000 years ago, you can today walk for hundreds upon hundreds of kilometres without encountering any other plant. Worldwide, wheat covers about 2.25 million square kilometres of the globe’s surface, almost ten times the size of Britain. How did this grass turn from insignificant to ubiquitous? Wheat did it by manipulating Homo sapiens to its advantage. This ape had been living a fairly comfortable life hunting and gathering until about 10,000 years ago, but then began to invest more and more effort in cultivating wheat. Within a couple of millennia, humans in many parts of the world were doing little from dawn to dusk other than taking care of wheat plants. It wasn’t easy. Wheat demanded a lot of them. Wheat didn’t like rocks and pebbles, so Sapiens broke their backs clearing fields. Wheat didn’t like sharing its space, water and nutrients with other plants, so men and women laboured long days weeding under the scorching sun. Wheat got sick, so Sapiens had to keep a watch out for worms and blight. Wheat was attacked by rabbits and locust swarms, so the farmers built fences and stood guard over the fields. Wheat was thirsty, so humans dug irrigation canals or lugged heavy buckets from the well to water it. Sapiens even collected animal faeces to nourish the ground in which wheat grew. The

against the velvet rope force fields that kept everyone without an invitation at bay. As I walked toward the entrance, the crowd bombarded me with a mix of insults, autograph requests, death threats, and tearful declarations of undying love. I had my body shield activated, but surprisingly, no one took a shot at me. I flashed the cyborg doorman my invitation, then mounted the long crystal staircase leading up into the club. Entering the Distracted Globe was more than a little disorienting. The inside of the giant sphere was completely hollow, and its curved interior surface served as the club’s bar and lounge area. The moment you passed through the entrance, the laws of gravity changed. No matter where you walked, your avatar’s feet always adhered to the interior of the sphere, so you could walk in a straight line, up to the “top” of the club, then back down the other side, ending up right back where you started. The huge open space in the center of the sphere served as the club’s zero-gravity “dance floor.” You reached it simply by jumping off the ground, like Superman taking flight, and then swimming through the air, into the spherical zero-g “groove zone.” As I stepped through the entrance, I glanced up—or in the direction that was currently “up” to me at the moment—and took a long look around. The place was packed. Hundreds of avatars milled around like ants crawling around the inside of a giant balloon. Others were already out on the dance floor—spinning, flying, twisting, and tumbling in time with the music, which thumped out of floating spherical speakers that drifted throughout the club. In the middle of all the dancers, a large clear bubble was suspended in space, at the absolute center of the club. This was the “booth” where the DJ stood, surrounded by turntables, mixers, decks, and dials. At the center of all that gear was the opening DJ, R2-D2, hard at work, using his various robotic arms to work the turntables. I recognized the tune he was playing: the ’88 remix of New Order’s “Blue Monday,” with a lot of Star Wars droid sound samples mixed in. As I made my way to the nearest bar, the avatars I passed all stopped to stare and point in

The granite complex inside the Great Pyramid, therefore, is poised ready to convert vibrations from the Earth into electricity. What is lacking is a sufficient amount of energy to drive the beams and activate the piezoelectric properties within them. The ancients, though, had anticipated the need for more energy than what would be collected only within the King's Chamber. They had determined that they needed to tap into the vibrations of the Earth over a larger area inside the pyramid and deliver that energy to the power center—the King's Chamber —thereby substantially increasing the amplitude of the oscillations of the granite. Modern concert halls are designed and built to interact with the instruments performing within. They are huge musical instruments in themselves. The Great Pyramid can be seen as a huge musical instrument with each element designed to enhance the performance of the other. While modern research into architectural acoustics might focus predominantly upon minimizing the reverberation effects of sound in enclosed spaces, there is reason to believe that the ancient pyramid builders were attempting to achieve the opposite. The Grand Gallery, which is considered to be an architectural masterpiece, is an enclosed space in which resonators were installed in the slots along the ledge that runs the length of the gallery. As the Earth's vibration flowed through the Great Pyramid, the resonators converted the vibrational energy to airborne sound. By design, the angles and surfaces of the Grand Gallery walls and ceiling caused reflection of the sound, and its focus into the King's Chamber. Although the King's Chamber also was responding to the energy flowing through the pyramid, much of the energy would flow past it. The specific design and utility of the Grand Gallery was to transfer the energy flowing through a large area of the pyramid into the resonant King's Chamber. This sound was then focused into the granite resonating cavity at sufficient amplitude to drive the granite ceiling beams to oscillation. These beams, in turn, compelled the beams above them to resonate in harmonic sympathy. Thus, with the input of sound and the maximization of resonance, the entire granite complex, in effect, became a vibrating mass of energy.

Get used to it. The weather may feel like science fiction, but the science underlying it is very real and mundane. It takes only a small increase in global average temperatures to have a big effect on weather, because what drives the winds and their circulation patterns on the surface of the earth are differences in temperature. So when you start to change the average surface temperature of the earth, you change the wind patterns—and then before you know it, you change the monsoons. When the earth gets warmer, you also change rates of evaporation—which is a key reason we will get more intense rainstorms in some places and hotter dry spells and longer droughts in others. How can we have both wetter and drier extremes at the same time? As we get rising global average temperatures and the earth gets warmer, it will trigger more evaporation from the soil. So regions that are already naturally dry will tend to get drier. At the same time, higher rates of evaporation, because of global warming, will put more water vapor into the atmosphere, and so areas that are either near large bodies of water or in places where atmospheric dynamics already favor higher rates of precipitation will tend to get wetter. We know one thing about the hydrologic cycle: What moisture goes up must come down, and where more moisture goes up, more will come down. Total global precipitation will probably increase, and the amount that will come down in any one storm is expected to increase as well—which will increase flooding and gully washers. That’s why this rather gentle term “global warming” doesn’t capture the disruptive potential of what lies ahead. “The popular term ‘global warming’ is a misnomer,” says John Holdren. “It implies something uniform, gradual, mainly about temperature, and quite possibly benign. What is happening to global climate is none of those. It is uneven geographically. It is rapid compared to ordinary historic rates of climatic change, as well as rapid compared to the adjustment times of ecosystems and human society. It is affecting a wide array of critically important climatic phenomena besides temperature, including precipitation, humidity, soil moisture, atmospheric circulation patterns, storms, snow and ice cover, and ocean currents and upwellings. And its effects on human well-being are and undoubtedly will remain far more negative than positive. A more accurate, albeit more cumbersome, label than ‘global warming’ is ‘global climatic disruption.’ 

No matter what level of instruction Marlboro Man gave me, no matter how many pointers, a horse trot for me meant a repeated and violet Slap! Slap! Slap! on the seat of my saddle. My feet were fine--they’d stay securely in the stirrups. But I just couldn’t figure out how to use the muscles in my legs correctly, and I hadn’t yet learned how to post. It was so unpleasant, the whole riding-a-horse business: my bottom would slap, my torso would stiffen, and I’d be sore for days--not to mention that I looked like a complete freak while riding--kind of like a tree trunk with red, stringy hair. Short of taking the rectal temperatures of cows, I’d never felt more out of place doing anything in my life. All of this rushed to the surface when I saw Marlboro Man walking toward me with two of his horses, one of which was clearly meant for me. Where’s my Jeep? I thought. Where’s my torch? I don’t want a horse. My bottom can’t take it. Where’s my Jeep? I’d never wanted to drive a Jeep so much. “Hey,” I said, walking toward him and smiling, trying to appear not only calm but also totally unconcerned about the reality that faced me. “Uh…I thought we were going burning.” I clearly sounded out the g. It was a loud, clanging cymbal. “Oh, we are,” he said, smiling. “But we’ve got to get to some areas the Jeep can’t reach.” My stomach lurched. For more than a couple of seconds, I actually considered feigning illness so I wouldn’t have to go. What can I say? I wondered. That I feel like I’m going to throw up? Or should I just clutch my stomach, groan, then run behind the barn and make dramatic retching sounds? That could be highly effective. Marlboro Man will feel sorry for me and say, “It’s okay…you just go on up to my house and rest. I’ll be back later.” But I don’t think I can go through with it; vomiting is so embarrassing! And besides, if Marlboro Man thinks I vomited, I might not get a kiss today… “Oh, okay,” I said, smiling again and trying to prevent my face from betraying the utter dread that plagued me. I hadn’t noticed, through all my inner torture and turmoil, that Marlboro Man and the horses had been walking closer to me. Before I knew it, Marlboro Man’s right arm was wrapped around my waist while his other hand held the reins of the two horses. In another instant, he pulled me toward him in a tight grip and leaned in for a sweet, tender kiss--a kiss he seemed to savor even after our lips parted. “Good morning,” he said sweetly, grinning that magical grin. My knees went weak. I wasn’t sure if it was the kiss itself…or the dread of riding.

THE BASIC LYING-DOWN POSTURE Begin by lying on your back on the floor or ground—a comfortable surface (firm, but not too hard)—with your knees up, your feet flat on the floor, and a yoga strap tied just above the knees. The strap should be tied tight enough so the knees are just touching or almost touching. We’re creating a triangle between the knees, the feet, and the floor, so that you can relax your thighs, lower back, and pelvic area. Your feet should be comfortably spread apart so that you feel stable and can fully relax. You may also want something supporting your head, such as a folded towel, a sweater, or a small pillow, to raise it slightly. Cross your hands at or over your lower belly with the left hand under the right hand, little fingers down toward the pubic bone, thumbs up toward the navel. This gathers your energy and awareness toward the core of the body. Feel the earth under you and let your body sink down as if into the earth. The more you can allow yourself to feel supported by the earth, the more fully you will be able to relax. Check the comfort of your position. You want to be really relaxed, so your body’s not being strained in any particular way. You should be holding yourself so you can completely relax the muscles in the lower back and the inner thighs and so there’s no effort of holding at all. You’re really relaxed: the triangle of your knees, two feet, and the floor should be very restful for you. Then, put your awareness in your body, and just let yourself continue to relax. Soon after you begin doing these practices, you’ll notice that any time you lie down in this way, in the same position with the intention to do body work, the body responds very quickly. This is the one time in our life when our body actually becomes the focus of attention. We’re not using the body for something else. We’re simply making a relationship with it as it is. It’s the only occasion when we ever do this, including in our sleep. The body begins to respond, to relax, to develop a sense of well-being, even in just taking this position. So just take a few minutes, and let your body completely relax. As you’re just lying there, you’ll notice that your body begins to let go. A muscle here, a muscle there, a tendon here, a joint there: it begins to release the tension in various places. It’s a very living situation. You might think, “Why am I here? There’s not much happening.” That’s not true at all. As long as you’re attentive and you put your awareness into your body, there’s a very dynamic, very lively process of relaxation that the body goes through. But you have to be present. You have to be in your body. You have to be intentionally and deliberately feeling your body for this to work.

3 INCIDENT IN THE ENGLISH CHANNEL Not long afterwards, a Belgian ferry, the Oudenbourg, was steaming its way from Ostende to Ramsgate. In the straits of Dover the duty officer noticed that half a mile south of its usual course there was something going on in the water. He could not be sure that there was no-one drowning there and so he ordered a change of course down to where the perturbance was taking place. Two hundred passengers on the windward side of the ship were shown a very strange spectacle: in some places a vertical jet of water shot out from the surface, and in some of those vertical jets there could be seen something like a black body thrown up with it; the surface of the sea for one or two hundred yards all around was tossing and seething wildly while, from the depths, a loud rattling and humming could be heard. "It was as if there was a small volcano erupting under the sea." As the Oudenbourg slowly approached the place an enormous wave rose about ten yards ahead of it and a terrible noise thundered out like an explosion. The entire ship was lifted violently and the deck was showered with a rain of water that was nearly boiling hot; and landing on the deck with the water was a strong black body which writhed and let out a sharp loud scream; it was a newt that had been injured and burnt. The captain ordered the ship full steam astern so that the ship would not steam straight into the middle of this turbulent Hell; but the water all around had also begun to erupt and the surface of the sea was strewn with pieces of dismembered newts. The ship was finally able to turn around and it fled northwards as fast as possible. Then there was a terrible explosion about six hundred yards to the stern and a gigantic column of water and steam, perhaps a hundred yards high, shot out of the sea. The Oudenbourg set course for Harwich and sent out a radio warning in all directions: "Attention all shipping, attention all shipping! Severe danger on Ostende-Ramsgate lane. Underwater explosion. Cause unknown. All shipping advised avoid area!" All this time the sea was thundering and boiling, almost as if military manoeuvres had been taking place under the water; but apart from the erupting water and steam there was nothing to see. From both Dover and Calais, destroyers and torpedo boats set out at full steam and squadrons of military aircraft flew to the site of the disturbance; but by the time they got there all they found was that the surface was discoloured with something like a yellow mud and covered with startled fish and newts that had been torn to pieces. At first it was thought that a mine in the channel must have exploded; but once the shores on both sides of the Straits of Dover had been ringed off with a chain of soldiers and the English prime-minister had, for the fourth time in the history of the world, interrupted his Saturday evening and hurried back to London, there were those who thought the incident must be of extremely serious international importance. The papers carried some highly alarming rumours, but, oddly enough, this time remained far from the truth; nobody had any idea that Europe, and the whole world with it, stood for a few days on the brink of a major war. It was only several years later that a member of the then British cabinet, Sir Thomas Mulberry, failed to be re-elected in a general election and published his memoirs setting out just what had actually happened; but by then, though, nobody was interested.

To paint after nature is to transfer three-dimensional corporeality to a two-dimensional surface. This you can do if you are in good health and not colorblind. Oil paint, canvas, and brush are material and tools. It is possible by expedient distribution of oil paint on canvas to copy natural impressions; under favorable conditions you can do it so accurately that the picture cannot be distinguished from the model. You start, let us say, with a white canvas primed for oil painting and sketch in with charcoal the most discernible lines of the natural form you have chosen. Only the first line may be drawn more or less arbitrarily, all the others must form with the first the angle prescribed by the natural model. By constant comparison of the sketch with the model, the lines can be so adjusted that the lines of the sketch will correspond to those of the model. Lines are now drawn by feeling, the accuracy of the feeling is checked and measured by comparison of the estimated angle of the line with the perpendicular in nature and in the sketch. Then, according to the apparent proportions between the parts of the model, you sketch in the proportions between parts on the canvas, preferably by means of broken lines delimiting these parts. The size of the first part is arbitrary, unless your plan is to represent a part, such as the head, in 'life size.' In that case you measure with a compass an imaginary line running parallel to a plane on the natural object conceived as a plane on the picture, and use this measurement in representing the first part. You adjust all the remaining parts to the first through feeling, according to the corresponding parts of the model, and check your feeling by measurement; to do this, you place the picture so far away form you that the first part appears as large in the painting as the model, and then you compare. In order to check a given proportion, you hold out the handle of your paintbrush at arm's length towards this proportion in such a way that the end of the thumbnail on the handle coincides with the other end of the proportion. If then you hold the paintbrush out towards the picture, again at arm's length, you can, by the measurement thus obtained, determine with photographic accuracy whether your feeling has deceived you. If the sketch is correct, you fill in the parts of the picture with color, according to nature. The most expedient method is to begin with a clearly recognizable color of large area, perhaps with a somewhat broken blue. You estimate the degree of matness and break the luminosity with a complimentary color, ultramarine, for example, with light ochre. By addition of white you can make the color light, by addition of black dark. All this can be learned. The best way of checking for accuracy is to place the picture directly beside the projected picture surface in nature, return to your old place and compare the color in your picture with the natural color. By breaking those tones that are too bright and adding those that are still lacking, you will achieve a color tonality as close as possible to that in nature. If one tone is correct, you can put the picture back in its place and adjust the other colors to the first by feeling. You can check your feeling by comparing every tone directly with nature, after setting the picture back beside the model. If you have patience and adjust all large and small lines, all forms and color tones according to nature, you will have an exact reproduction of nature. This can be learned. This can be taught. And in addition, you can avoid making too many mistakes in 'feeling' by studying nature itself through anatomy and perspective and your medium through color theory. That is academy.