Green Hydrogen Quotes

All the green in the planted world consists of these whole, rounded chloroplasts wending their ways in water. If you analyze a molecule of chlorophyll itself, what you get is one hundred thirty-six atoms of hydrogen, carbon, oxygen, and nitrogen arranged in an exact and complex relationship around a central ring. At the ring's center is a single atom of magnesium. Now: If you remove the atom of magnesium and in its exact place put an atom of iron, you get a molecule of hemoglobin. The iron atom combines with all the other atoms to make red blood, the streaming red dots in the goldfish's tail.

Let's see if we can find from hydrogen peroxide for these bloodstains in the carpet,' Grace said. 'I prefer ammonia,' Mrs. Greene said. 'Hot water?' Grace asked. 'No, cold.' 'Interesting,' Grace said.

Ethanol is a volatile, flammable, colourless liquid with a slight chemical odour. It is used as an antiseptic, a solvent, in medical wipes and antibacterial formulas because it kills organisms by denaturing their proteins. Ethanol is an important industrial ingredient. Ethanol is a good general purpose solvent and is found in paints, tinctures, markers and personal care products such as perfumes and deodorants. The largest single use of ethanol is as an engine fuel and fuel additive. In other words, we drink, for fun, the same thing we use to make rocket fuel, house paint, anti-septics, solvents, perfumes, and deodorants and to denature, i.e. to take away the natural properties of, or kill, living organisms. Which might make sense on some level if we weren’t a generation of green minded, organic, health-conscious, truth seeking individuals. But we are. We read labels, we shun gluten, dairy, processed foods, and refined sugars. We buy organic, we use natural sunscreen and beauty products. We worry about fluoride in our water, smog in our air, hydrogenated oils in our food, and we debate whether plastic bottles are safe to drink from. We replace toxic cleaning products with Mrs. Myers and homemade vinegar concoctions. We do yoga, we run, we SoulCycle and Fitbit, we go paleo and keto, we juice, we cleanse. We do coffee enemas and steam our yonis, and drink clay and charcoal, and shoot up vitamins, and sit in infrared foil boxes, and hire naturopaths, and shamans, and functional doctors, and we take nootropics and we stress about our telomeres. These are all real words. We are hyper-vigilant about everything we put into our body, everything we do to our body, and we are proud of this. We Instagram how proud we are of this, and we follow Goop and Well+Good, and we drop 40 bucks on an exercise class because there are healing crystals in the floor. The global wellness economy is estimated to be worth $4 trillion. $4 TRILLION DOLLARS. We are on an endless and expensive quest for wellness and vitality and youth. And we drink fucking rocket fuel.

IN 1953, STANLEY Miller, a graduate student at the University of Chicago, took two flasks—one containing a little water to represent a primeval ocean, the other holding a mixture of methane, ammonia, and hydrogen sulphide gases to represent Earth’s early atmosphere—connected them with rubber tubes, and introduced some electrical sparks as a stand-in for lightning. After a few days, the water in the flasks had turned green and yellow in a hearty broth of amino acids, fatty acids, sugars, and other organic compounds. “If God didn’t do it this way,” observed Miller’s delighted supervisor, the Nobel laureate Harold Urey, “He missed a good bet.

The sunlike energy released by the fusion of atoms of the lightest element, hydrogen, is detonated by the fission of one of the heaviest, plutonium, named after the god of the underworld.

Chloroplasts bear chlorophyll; they give the green world its color, and they carry out the business of photosynthesis. Around the inside perimeter of each gigantic cell trailed a continuous loop of these bright green dots. They spun . . . they pulsed, pressed, and thronged . . . they shone, they swarmed in ever-shifting files around and around the edge of the cell; they wandered, they charged, they milled, raced . . . they flowed and trooped greenly . . . All the green in the planted world consists of these whole, rounded chloroplasts . . . If you analyze a molecule of chlorophyll itself, what you get is one hundred thirty-six atoms of hydrogen, carbon, oxygen, and nitrogen arranged in an exact and complex relationship around a central ring. At the ring’s center is a single atom of magnesium. Now: If you remove the atom of magnesium and in its place put an atom of iron, you get a molecule of hemoglobin. The iron atom combines with all the other atoms to make red blood, the streaming red dots in the goldfish’s tail.

By one billion years ago, plants, working cooperatively, had made a stunning change in the environment of the Earth. Green plants generate molecular oxygen. Since the oceans were by now filled with simple green plants, oxygen was becoming a major constituent of the Earth’s atmosphere, altering it irreversibly from its original hydrogen-rich character and ending the epoch of Earth history when the stuff of life was made by nonbiological processes. But oxygen tends to make organic molecules fall to pieces. Despite our fondness for it, it is fundamentally a poison for unprotected organic matter. The transition to an oxidizing atmosphere posed a supreme crisis in the history of life, and a great many organisms, unable to cope with oxygen, perished. A few primitive forms, such as the botulism and tetanus bacilli, manage to survive even today only in oxygen-free environments. The nitrogen in the Earth’s atmosphere is much more chemically inert and therefore much more benign than oxygen. But it, too, is biologically sustained. Thus, 99 percent of the Earth’s atmosphere is of biological origin. The sky is made by life.

But water is not segregated. Its beauty is not simply decorative. It connects and holds. Billions of years ago life began using water to construct itself; life had always lived in water and been aqueous, but it had not always derived its hydrogen atoms from water. Early life used hydrogen sulfide or even elemental hydrogen, but crafty microbes found a way to crack the chemical bonds of water molecules to get at and incorporate hydrogen into their bodies. This original green party painted the planet the color of spring, and descendants of the water users survive as plastids held aloft in the durable scaffolding of those savvy transporters of water from the ground to the air: plants.

Foods to Embrace: Probiotics: Yogurt with active cultures, tempeh, miso, natto, sauerkraut, kefir, kimchi, kombucha, buttermilk, and certain cheeses. Prebiotics: Beans, oats, bananas, berries, garlic, onions, dandelion greens, asparagus, Jerusalem artichokes, and leeks. Low-GI carbohydrates: Brown rice, quinoa, steel-cut oatmeal, and chia seeds. Medium-GI foods, in moderation: Honey, orange juice, and whole-grain bread. Healthy fats: Monounsaturated fats like olive oil, nuts, nut butters, and avocados. Omega-3 fatty acids: Fish, especially fatty fish like salmon, mackerel, tuna, herring, and sardines. Vitamins B9, B12, B1, B6, A, and C. Minerals and micronutrients: Iron, magnesium, potassium, zinc, and selenium. Spices: Saffron and turmeric. Herbs: Oregano, lavender, passionflower, and chamomile. Foods to Avoid: Sugar: Baked goods, candy, soda, or anything sweetened with sugar or high-fructose corn syrup. High-GI carbs: White bread, white rice, potatoes, pasta, and anything else made from refined flour. Artificial sweeteners: Aspartame is particularly harmful, but also saccharin, sucralose, and stevia in moderation and with caution. Fried foods: French fries, fried chicken, fried seafood, or anything else deep-fried in oil. Bad fats: Trans fats such as margarine, shortening, and hydrogenated oils are to be avoided totally; omega-6 fats such as vegetable, corn, sunflower, and safflower oil should only be consumed in moderation. Nitrates: An additive used in bacon, salami, sausage, and other cured meats.

The last refuge of the Self, perhaps, is “physical continuity.” Despite the body’s mercurial nature, it feels like a badge of identity we have carried since the time of our earliest childhood memories. A thought experiment dreamed up in the 1980s by British philosopher Derek Parfit illustrates how important—yet deceiving—this sense of physical continuity is to us.15 He invites us to imagine a future in which the limitations of conventional space travel—of transporting the frail human body to another planet at relatively slow speeds—have been solved by beaming radio waves encoding all the data needed to assemble the passenger to their chosen destination. You step into a machine resembling a photo booth, called a teletransporter, which logs every atom in your body then sends the information at the speed of light to a replicator on Mars, say. This rebuilds your body atom by atom using local stocks of carbon, oxygen, hydrogen, and so on. Unfortunately, the high energies needed to scan your body with the required precision vaporize it—but that’s okay because the replicator on Mars faithfully reproduces the structure of your brain nerve by nerve, synapse by synapse. You step into the teletransporter, press the green button, and an instant later materialize on Mars and can continue your existence where you left off. The person who steps out of the machine at the other end not only looks just like you, but etched into his or her brain are all your personality traits and memories, right down to the memory of eating breakfast that morning and your last thought before you pressed the green button. If you are a fan of Star Trek, you may be perfectly happy to use this new mode of space travel, since this is more or less what the USS Enterprise’s transporter does when it beams its crew down to alien planets and back up again. But now Parfit asks us to imagine that a few years after you first use the teletransporter comes the announcement that it has been upgraded in such a way that your original body can be scanned without destroying it. You decide to give it a go. You pay the fare, step into the booth, and press the button. Nothing seems to happen, apart from a slight tingling sensation, but you wait patiently and sure enough, forty-five minutes later, an image of your new self pops up on the video link and you spend the next few minutes having a surreal conversation with yourself on Mars. Then comes some bad news. A technician cheerfully informs you that there have been some teething problems with the upgraded teletransporter. The scanning process has irreparably damaged your internal organs, so whereas your replica on Mars is absolutely fine and will carry on your life where you left off, this body here on Earth will die within a few hours. Would you care to accompany her to the mortuary? Now how do you feel? There is no difference in outcome between this scenario and what happened in the old scanner—there will still be one surviving “you”—but now it somehow feels as though it’s the real you facing the horror of imminent annihilation. Parfit nevertheless uses this thought experiment to argue that the only criterion that can rationally be used to judge whether a person has survived is not the physical continuity of a body but “psychological continuity”—having the same memories and personality traits as the most recent version of yourself. Buddhists

You are God. You want to make a forest, something to hold the soil, lock up energy, and give off oxygen. Wouldn’t it be simpler just to rough in a slab of chemicals, a green acre of goo? You are a man, a retired railroad worker who makes replicas as a hobby. You decide to make a replica of one tree, the longleaf pine your great-grandfather planted- just a replica- it doesn’t have to work. How are you going to do it? How long do you think you might live, how good is your glue? For one thing, you are going to have to dig a hole and stick your replica trunk halfway to China if you want the thing to stand up. Because you will have to work fairly big; if your replica is too small, you’ll be unable to handle the slender, three-sided needles, affix them in clusters of three in fascicles, and attach those laden fascicles to flexible twigs. The twigs themselves must be covered by “many silvery-white, fringed, long-spreading scales.” Are your pine cones’ scales “thin, flat, rounded at the apex?” When you loose the lashed copper wire trussing the limbs to the trunk, the whole tree collapses like an umbrella. You are a sculptor. You climb a great ladder; you pour grease all over a growing longleaf pine. Next, you build a hollow cylinder around the entire pine…and pour wet plaster over and inside the pine. Now open the walls, split the plaster, saw down the tree, remove it, discard, and your intricate sculpture is ready: this is the shape of part of the air. You are a chloroplast moving in water heaved one hundred feet above ground. Hydrogen, carbon, oxygen, nitrogen in a ring around magnesium…you are evolution; you have only begun to make trees. You are god- are you tired? Finished?

Sean was watching me, though. And Sean wiped the bryozoa residue from his hand across my stomach. This was the third time a boy had ever touched my bare tummy, and I’d had enough. Through gritted teeth, like any extra movement might spread the bryozoa further across my skin, I told him, “I like you less than I did.” I bailed over the side of the boat-the side opposite where the bryozoa returned to its native habitat. Deep in the warm water, I scrubbed at my tummy with both hands. A combination of bryozoa waste and Sean germs: it was the best of times, it was the worst of times. Leaning toward worst, because now I had slime on my hands. Or maybe this was psychosomatic. Holding my hands open in front of me in the water, I didn’t see any slime. I rubbed my hands together anyway. Something dove into the water beside me in a rush of bubbles. I came up for air. Sean surfaced, too, tossing sparkling drops of water from his hair. “You still like me a lot, though, right?” “No prob. Green is the new black.” Giving up on getting clean, I swam a few strokes back toward the platform to get out again. What I needed was a shower with chlorinated water and disinfectant soap. I might need to bubble out my belly button with hydrogen peroxide. “What if I made it up to you?” He splashed close behind me. “What if I helped you get clean? We don’t want you dirty.” He moved both hands around me under the water, up and down across my tummy. It was the fourth time a boy had touched my tummy! And it was very awkward. He bobbed so close behind me that I had a hard time treading water without kicking him. I needed to choose between flirting and breathing. Cameron and my brother leaned over the side of the boat and gaped at us, which didn’t help matters. I’d been afraid of this. Flirting with Sean was no fun if the other boys acted like we were lepers. Well, okay, it was fun, but not as fun as it was supposed to be. Obviously I would need to give McGullicuddy the little dolphin talk. I wasn’t sure I could do this with Cameron-Cameron and I didn’t have heart-to-heart convos-but I might need to make an exception, if he continued to watch us like we were a dirty movie on Pay-Per-View (which I’d also seen a lot of. Life with boys). BEEEEEEEEEEEEEEEE- Sean and I started and turned toward the boat. Still behind the steering wheel, Adam had his chin in his hand and his elbow on the horn. -EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE Damn it! I turned around to face Sean and gave him a wry smile, but he’d already taken his hands away from my tummy. The horn really ruined the mood. -EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE Sean hauled himself up onto the platform. I followed close behind him, and (glee!) he put out a hand to help me. Cameron and my brother yelled at Adam. -EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEP. “Oh!” Adam said as if he’d had no idea he’d been laying on the horn. He looked at his elbow like it belonged to someone else. I was in the boat with Sean now, and he was still holding my hand. Or, maybe I was still clinging to his hand, but this is a question of semantics. In any case, I pulled him by the hand past the other boys to the bow. We didn’t have privacy. There was no privacy on a wakeboarding boat. At least we had the boat’s windshield between us and the others. As I turned to sit down on the bench, I stuck out my tongue at Adam behind the windshield. He crossed his eyes at me.

For instance, a black hole as light as a small asteroid would emit about as much radiation as a million-megaton hydrogen bomb, with radiation concentrated in the gamma-ray part of the electromagnetic spectrum.

Indeed, much of Tarter’s pitch, whether at speaking engagements or within SETI promotional materials, has a soaring, cinematic feel. Among her most captivating lines: “We are what happens when a primordial mixture of hydrogen and helium evolve for so long that it begins to ask where it came from. This is us, contemplating ourselves.

INGREDIENTS: • 1 Cup Dawn Dish Detergent • 2 Cups Hydrogen Peroxide DIRECTIONS: 1. Mix ingredients together and pour directly over stain. 2. Watch it disappear!

All atomic nuclei are composed of two types of particles: protons and their electrically neutral partners, neutrons. If a nucleus has too many of one type or the other, then the rules of quantum mechanics dictate that the balance has to be redressed and those excess particles will change into the other form: protons will become neutrons, or neutrons protons, via a process called beta-decay. This is precisely what happens when two protons come together: a composite of two protons cannot exist and one of them will beta-decay into a neutron. The remaining proton and the newly transformed neutron can then bind together to form an object called a deuteron (the nucleus of an atom of the heavy hydrogen isotopefn3 called deuterium), after which further nuclear reactions enable the building of the more complex nuclei of other elements heavier than hydrogen, from helium (with two protons and either one or two neutrons) through to carbon, nitrogen, oxygen, and so on. The key point is that the deuteron owes its existence to its ability to exist in two states simultaneously, by virtue of quantum superposition. This is because the proton and neutron can stick together in two different ways that are distinguished by how they spin. We will see later how this concept of ‘quantum spin’ is actually very different from the familiar spin of a big object, such as a tennis ball; but for now we will go with our classical intuition of a spinning particle and imagine both the proton and the neutron spinning together within the deuteron in a carefully choreographed combination of a slow, intimate waltz and a faster jive. It was discovered back in the late 1930s that within the deuteron these two particles are not dancing together in either one or the other of these two states, but in both states at the same time – they are in a blur of waltz and jive simultaneously – and it is this that enables them to bind together.fn4 An obvious response to this statement is: ‘How do we know?’ Surely, atomic nuclei are far too small to be seen, so might it not be more reasonable to assume that there is something missing in our understanding of nuclear forces? The answer is no, for it has been confirmed in many laboratories over and over again that if the proton and neutron were performing the equivalent of either a quantum waltz or a quantum jive, then the nuclear ‘glue’ between them would not be quite strong enough to bind them together; it is only when these two states are superimposed on top of each other – the two realities existing at the same time – that the binding force is strong enough. Think of the two superposed realities as a little like mixing two coloured paints, blue and yellow, to make a combined resultant colour, green. Although you know the green is made up of the two primary constituent colours, it is neither one nor the other. And different ratios of blue and yellow will make different shades of green. Likewise, the deuteron binds when the proton and neutron are mostly locked in a waltz, with just a tiny amount of jive thrown in. So

The core physics relies on a process known as quantum tunneling. Imagine a particle, an electron for instance, encountering a solid barrier, say a slab of steel ten feet think, that classical physics predicts it can't penetrate. A hallmark of quantum mechanics is that the rigid classical notion of "can't penetrate" often translates into the softer quantum declaration of "has a small but nonzero probability of penetrating." The reason is that the quantum jitters of a particle allow it, every so often, to suddenly materialize on the other side of an otherwise impervious barrier. The moment at which such quantum tunneling happens is random; the best we can do is predict the likelihood that it will take place during one interval or another. But the math says that if you wait long enough, penetration through just about any barrier will happen. And it does happen. If it didn't, the sun wouldn't shine: for hydrogen nuclei to get close enough to fuse, they must tunnel through the barrier created by the electromagnetic repulsion of their protons.

by the time the universe was a couple of minutes old, it was filled with a nearly uniform hot gas composed of roughly 75 percent hydrogen, 23 percent helium, and small amounts of deuterium and lithium. The essential point is that this gas filling the universe had extraordinarily low entropy. The big bang started the universe off in a state of low entropy, and that state appears to be the source of the order we currently see. In other words, the current order is a cosmological relic.

All of us are radioactive. We, and our environment, exist by virtue of green plants that capture photons, the basic units of light energy - they are produced by thermonuclear fusion within the Sun. Plants use these photons via photosynthesis to separate water into hydrogen and oxygen. The hydrogen is then combined with carbon dioxide from the atmosphere to produce glucose, which the plant burns to produce energy. The oxygen is released into the atmosphere, and we and virtually all other living creatures breathe it. Energy produced by burning glucose is transferred to us when we eat plants, or animals that fee on plants or plant products.

Currently, hydrogen is mostly generated from non-renewable sources, almost 90% from steam reforming of natural gas and naphtha, and coal gasification [71]. Researches have been focused on the production of hydrogen from renewable resources, biomass, which is plenty uniformly available in all countries and considered sustainable

For the production of green diesel, hydroprocessing is used to saturate the unsaturated double bonds and remove oxygen. The production of green diesel is performed through hydrodeoxygenation, decarboxylation, decarbonylation, cracking, and hydrogenation reactions.

Technologies such as biomass pyrolysis and gasification have possessed several advantages due to their abundance, low cost, and CO2 neutrality [4, 30]. Therefore, finding an alternative method for the production of hydrogen will enhance the hydroprocessing production efficiencies toward commercialization and lead to a complete green technology for producing green diesel.

During this process, the feedstock reacts with hydrogen in the presence of catalysts at high temperatures (300–400 °C) and pressure of almost 10 MPa. Heterogeneous catalysts like Ni–Mo/Al2O3 and Co–Mo/Al2O3 are used in this process to produce hydrocarbons in the range of C15–C18. Hydrotreatment also results in the removal of heteroatoms like oxygen, nitrogen, and sulfur [81]. Green Diesel has a similar chemical composition as that of petrodiesel and can be used in existing refinery infrastructure such as pipelines and storage tanks. It has similar advantages to that of biodiesel in terms of its use in diesel engines without any engine modification. It can be either used in its pure form or can be blended with petrodiesel [78]. Although several other methods are being developed to produce green diesel, hydrotreatment is mostly accepted and is also commercially available

Hydrogen plays a significant role in hydroprocessing technology, which can be obtained from different sources such as fossil fuels, biomass, and waste.

I was not in the right frame of mind to slowly vent fifteen condoms of hydrogen out my window that night, but that's what I did.

The cyanobacteria, a group of photosynthetic bacteria tinted blue-green by chlorophyll and other pigments, harvest sunlight and fix CO2 much like eukaryotic algae and land plants. However, when hydrogen sulfide (H2S, well known for its “rotten egg” smell) is present, many cyanobacteria use this gas rather than water to supply the electrons needed for photosynthesis. Sulfur and sulfate are formed as by-products, but oxygen is not.

That something is everywhere and always amiss is part of the very stuff of creation. It is as though each clay form had baked into it, fired into it, a blue streak of nonbeing, a shaded emptiness like a bubble that not only shapes its very structure but that also causes it to list and ultimately explode. We could have planned things more mercifully, perhaps, but our plan would never get off the drawing board until we agreed to the very compromising terms that are the only ones that being offers. The world has signed a pact with the devil; it had to. It is a covenant to which every thing, even every hydrogen atom, is bound. The terms are clear: if you want to live, you have to die; you cannot have mountains and creeks without space, and space is a beauty married to a blind man. The blind man is Freedom, or Time, and he does not go anywhere without his great dog Death. The world came into being with the signing of the contract. A poet says, “the force that through the green fuse drives the flower/drives my green age.