On and off, I have been developing coatings for over 30 years. It has been one of my favorite occupations. Coatings are very interesting from a scientific point of view (they have lots of surface area) and from a technical point of view. Coatings are used mostly to protect and preserve products, but they can also be used to impart properties to the base material of the product that the product would not otherwise have, such as color and other optical properties such as emissivity. Properties such as easy release of ice, water replency, and antifouling can also be imparted. In one project, I was assigned the task of developing a non-catalytic coating. I was asked to do this by NASA. They were working on hypersonic vehicle designs.
Hypersonic vehicles go faster than the speed of sound. Much faster, say somewhere between 5 and 25 times the speed of sound. At those speeds, the skin of the hypersonic vehicle gets hot, very hot. How hot, well, that depends on a lot of things such as the shape of the vehicle and properties of the skin of the plane such as emissivity. That's the second time I have mentioned emissivity so I should explain what it is. Emissivity is an optical property of a surface that controls how efficiently the surface radiates heat: the higher the emissivity, the more efficiently the surface radiates heat and, in an environment such as that formed in hypersonic travel, emissivity controls how hot or cool a surface becomes. Emissivity is thus an important property to control, and it can be controlled with coatings. For the environments created by hypersonic travel, though, it is not the only important surface property that needs to be controlled. Catalicity, or catalytic efficiency, is an important surface property that can have dramatic effects on the transfer of heat from the air flowing around the vehicle to the surface of the vehicle.
So why do hypersonic vehicles get hot? It's for the same reasons that meteoroids burn up on entering the earth's atmosphere. The usual explanation given for this is atmospheric friction. This explanation is not quite right. There is some pretty complex physics and chemistry going on. As a meteoroid or hypersonic vehicle travels through the atmosphere, a shock wave forms in front of it. That shock wave contains some very energetic gas, which is one of the reasons that meteors are visible streaks of light in the night sky. The gas in the shock layer has enough energy to make the gas glow and even to melt the surface of the meteoroid. For hypersonic vehicles, melting the surface would seem to be something that we want to avoid. That's not always true. The coatings on the surface of the Apollo space capsules were designed to melt and "ablate" during reentry. Ablation was used to absorb the heat and then evaporate taking the heat away and keeping the space capsule cool. For reusable hypersonic vehicles, ablation is not a great strategy. Something more permanent is needed and you need a different strategy. To find that strategy, looking at the details of what's going on is crucial. I said that some pretty complex physics and chemistry is going on in that shock layer. One thing that is happening is that the gas is dissociating and ionizing. The gas in our atmosphere primarily comprises two gases: nitrogen and oxygen. Other gases are present in very small quantities such as argon, water vapor and carbon dioxide. Nitrogen and oxygen, in the earth's atmosphere, are present as the molecules dinitrogen and dioxygen. In other words, nitrogen is present as a molecule comprising two nitrogen atoms, dinitrogen, and oxygen is present as a molecule comprising two oxygen atoms, dioxygen. This is important because, in the shock wave, the molecules of nitrogen and oxygen can dissociate into their atomic forms. At first, this is a good thing. Dissociation of these molecules into their atomic forms uses up some of the energy in the shock wave so there is less energy available for heating the meteor or hypersonic vehicle. Oxygen tends to dissociate first and then nitrogen at higher energies. So far, so good. But, here's the down side: once you have atomic oxygen and nitrogen present in the gas surrounding the meteoroid or atmospheric vehicle, they are chemically very active. That's where the properties of the surfaces becomes important. If the surface is a good catalyst, and the surface of most meteoroids are, the transfer of heat to the surface is greatly enhanced by the recombination of the atomic oxygen and nitrogen. If recombination can be avoided, you get the upside of dissociation, less sensible heat in the surrounding gas, without the downside of more efficient transfer of heat. Hence, the request by NASA to develop non-catalytic coatings for its hypersonic vehicle designs.
As you can see, developing coatings is a highly interesting field and one that takes you into many areas of science and technology that you would not initially expect. And that's what I love about developing coatings: there's so much to learn.
What an interesting field! Relevant to almost anything, from shoes to shovels, I imagine.
ReplyDeleteA very astute observation Rod. The important thing to realize is that when you work with coatings, they become part of a system and work together with the other materials in the object or product that you are coating. This working together is highly important. Some coatings are applied as “sacrificial layers.” They are called sacrificial because it is their function to absorb the environment’s initial attack. Most of the time, we think of the environment as a friendly thing and something that we need to protect. When you are thinking along coating lines, you can arrive at a surprisingly different point of view. The environment can be very destructive to the things we use: we and the things we use need to be protected from the environment! I am not trying to be funny or clever here. Think about how rust and corrosion can ruin things. Rust and corrosion are natural processes: it’s part of the natural cycle. We win things from the earth (winning is technical jargon for the mining and refining of materials) and to the earth they will return. It’s all natural. But we would like to slow down portions of the natural cycle sometimes so that we can enjoy the benefits of our labors just a little longer.
ReplyDeleteI have a particular interest in the current Bloodhound SSC project - as an inexpert observer, because I am no scientist. I don't know if it has had much coverage on your side of the pond. The aim is to push the land speed record up to 1,000 mph, using combined jet and rocket propulsion. Computational fluid dynamics has been fundamental to the design process, but I'm not sure what if any thought has been given to surface coatings. Do you think these would be relevant - for example to reducing friction in the context of drag or heat?
ReplyDeleteThe short answer, is no. Not directly. But the question is very intriguing and I think that it deserves a better and fuller answer. Let me try to do that as a post. It will take me a little time. Your comment touches on so many topics that seem important to me. I need to marshal my thoughts and put them in order.
DeleteThank you, Karl. I hadn't intended to saddle you with anything onerous...
ReplyDeleteNot onerous. Not the least bit. I welcome your comments and find them interesting.
DeleteThere are a couple of posts available based on your comment about the Bloodhound SSC project. I hope that you get a chance to see them if you are interested. You can find them at http://coatingdeveloper.blogspot.com/.
DeleteI had been keeping an eye open for your post, but in the wrong place. Found them now, and they are extremely interesting and insightful. In fact I need to reread them to fully absorb them. You have chosen a fascinating and, I imagine, minority field - but one which must be ever more relevant as technological demands and what can be achieved to meet them increase in tandem. Many thanks.
ReplyDeleteThank you for your interest. Your comments and your directing me to the Bloodhound SSC project were very helpful. They provided some focus and a starting point. The Bloodhound SSC vehicle will be loaded with coatings, many of them very high-tech coatings. I'll get around to talking about some of them later.
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