This picture shows what hydrogen atoms might look like if we could see them.

The chart above shows the appearance of a single hydrogen atom in a few of its lowest excited states. In each of those states, the electron is found in a different orbital, some of which have unfamiliar shapes. But even the term “shape” is a little funny for something that you can’t hold in your hand. These are actually probability density plots, which show the likelihood of observing the electron in any one position at a given time– and more correctly, 2D projections of 3D probability densities.

So even the humble hydrogen atom can be a bit complex. Fortunately, we have advanced technology that can help us cut though the quantum mechanical haze: Cookies!

What we can see (and taste) are cookies made to resemble the shapes of the hydrogen atoms in the chart. The folks at Evil Mad Scientist Laboratories made these cookies and will show you how you can make them, too! Link

Link.  Blog with video explanation.  via kottke.

Alan Friedman, a greeting cards-maker by day and astronomer by night, took this amazing photo of the Sun. APOD explains why it’s blue:

Our Sun may look like all soft and fluffy, but it’s not. Our Sun is an extremely large ball of bubbling hot gas, mostly hydrogen gas. The above picture of our Sun was taken last month in a specific red color of light emitted by hydrogen gas called Hydrogen-alpha and then color inverted to appear blue. In this light, details of the Sun’s chromosphere are particularly visible, highlighting numerous thin tubes of magnetically-confined hot gas known as spicules rising from the Sun like bristles from a shag carpet. Our Sun glows because it is hot, but it is not on fire. Fire is the rapid acquisition of oxygen, and there is very little oxygen on the Sun. The energy source of our Sun is the nuclear fusion of hydrogen into helium deep within its core. No sunspots or large active regions were visible on the Sun this day, although some solar prominences are visible around the edges.

For a larger pic, be sure to check out APOD: Link

Gerardine Botte, an Ohio University professor, sees the liquid as a solution thanks to the particular composition of its major component, urea. Its make-up, a 2-to-1 ratio of hydrogen and nitrogen, is convenient because hydrogen can be extracted from nitrogen using much less electricity than that needed to, say, pull apart hydrogen and oxygen. (It’s a matter of 0.037 Volts versus 1.23 Volts, if you really need to know.)

Botte has recently come up with a nickel-based electrode that can do just that: dip the electrode into urine, apply electrical current, and voila, hydrogen is released. While the research is still in an initial phase, it’s possible that urine could power cars, homes, and various devices in as near of a future as six months from now.

Link

Sabotage

This one is for all of the conspiracy theorists out there, but it was widely believed to be the culprit at the time thanks to three pretty credible believers in the theory: Hugo Eckener (pictured), who used to be the head of the Zeppelin company; Charles Rosenthal, commander of the Lakehurst Naval Air Station; and Max Pruss, the Hindenburg’s commander.

When Eckener heard the zeppelin had “exploded,” he immediately thought that someone had intentionally destroyed the airship. Pruss found it hard to believe that something as petty as static would ignite the fabric of the Hindenburg; he said he personally had piloted airships through thunderstorms and that they had even been struck by lightning with no ill effects.

So who would have done such a terrible thing? A couple of books have named the zeppelin’s rigger, Eric Spehl. The fire started in an area that he and his fellow riggers had exclusive access to, and another rigger reported seeing a flash like a flashbulb just before the whole thing went up in flames. Spehl’s hobby – amateur photography – made it seem likely that he knew which types of flash could serve as an igniter.

Another suspect was a passenger named Joseph Späh, a German acrobat who was traveling with his dog, Ulla. He drew suspicion because of his many trips to the freight room by the ship’s stern, supposedly to feed his dog. Stewards said he seems particularly irritated that the flight was running late, and others speculated that his acrobatic career would make it easy for him to climb around in the catwalks to plant a bomb. Späh was cleared and Spehl died in the fire, so we’ll never know if one of them was responsible. One rumor even said that Hitler ordered the disaster because Hugo Eckener was anti-Nazi.

Why the theory is probably wrong: Even Eckener changed his mind: when he later watched the tapes and learned that the ‘Burg had burned, not exploded, he reversed his theory to the static spark theory (see below). And no evidence of a bomb was ever found in the wreckage. They did find some yellow substance originally believed to be sulfur, which can ignite hydrogen, but it was later determined that it was probably just residue from a fire extinguisher, and none of the residue was found anywhere near the stern of the ship.

Static Spark

You know how when it’s particularly dry, you can shuffle along your carpet and shock the crap out of someone sitting on the couch? Same theory, but bigger. The Hindenburg was really behind on its flight schedule – more than 12 hours, in fact. To try to make up for lost time, they flew directly through a storm front with lots of humidity and electrical charge. Between that and a light rain falling at Lakehurst, the mooring lines probably got a bit wet. When they touched down to land, the lines would have grounded the frame they were connected to, but not the fabric stretched around the frame. So when the static electricity sparked, the fabric went up in flames.

Another sub-theory is that hydrogen gas was in the air, perhaps due to a leak, and the static spark ignited the gas. Both of these seem pretty plausible when you consider that historian Douglas Robinson recorded an eyewitness account from one of the passengers saying that he saw St. Elmo’s fire just before the fire fully broke out. Not the ‘80s movie starring Demi Moore and Rob Lowe, the actual electrical weather phenomenon. He had enough time to tell his wife, “Oh, heavens, the thing is afire,” and showed her where the St. Elmo’s fire was occurring before the fabric ignited.

Lightning

Coming from such a credible source – the former director of NASA’s Marshall Space Flight Center – this one seems like it could be true as well. He says it’s not the fact that the ship was struck by lightning that was its downfall – the ship had been struck before and it was fine. It’s because it was landing as it was hit. As it landed, the Hindenburg dispelled hydrogen to lessen its weight and land. The hydrogen mixed with the oxygen in the air and the lightning ignited the fumes.

Why it could be wrong: The fire appeared in a wave motion, which Eckener believed was more apt to happen with a static spark than a lightning bolt.

Incendiary Paint

Mythbusters tackled this one and declared it Busted, but I’ll tell you the theory anyway. The fabric (pictured) around the Hindenburg’s frame had been painted with what they called “dope,” a substance that made the fabric stiff and airtight. However, the substances it was made of were highly flammable in liquid form and still pretty unstable even when dry. The Incendiary Paint Theory says that the volatile substances reacted and caused the spark.

Why the theory is probably not true: The “dope,” which is actually cellulose acetate butyrate, is classified as burning easily if it catches fire, but it doesn’t actually ignite easily and will self-extinguish if there isn’t an external source keeping it burning. Some of the fabric survived the fire, which leads experts to believe the fabric didn’t actually start the fire. The Mythbusters test found just that – while the stuff used to paint the skin was definitely flammable, it wasn’t enough to ignite and destroy the Hindenburg all on its own.

Puncture Theory

It’s easy enough to believe: one of the bracing wires came loose, snapped, and punctured one of the internal gas cells. This would have caused the hydrogen leak believed to have happened in other theories. Then the static spark theory would have happened, igniting the fumes from the punctured cell. It’s also thought that when the wire struck the cell, it caused a spark which ignited the fire.

The Indiana Jones Theory

Turns out this guy didn’t have a ticket, and a fight ensued, and in the melee a gas tank got punctured. Sorry, I couldn’t resist.