Tech: SwRI, UTSA researchers work to better understand hypersonic flight environments


IMAGE: As the air begins to decompose around an object moving at hypersonic speed, re-searchers pointed a laser at the molecules, which absorb the light briefly and then emit it in…
view more 

Credit: Christopher Combs/UTSA

SAN ANTONIO — July 28, 2020 — Researchers from Southwest Research Institute (SwRI) and The University of Texas at San Antonio (UTSA) are working to develop un-obtrusive diagnostics for hypersonic flight testing. The project led by Dr. Nicholas J. Mueschke of SwRI’s Mechanical Engineering Division and Dr. Christopher Combs of UTSA’s College of Engineering is supported by a $125,000 grant from the Connecting through Research Partnerships (CONNECT) program.

“The goal is to ultimately make full aerodynamic measurements in a truly representa-tive hypersonic environment,” Mueschke said. “”These measurements will directly contribute to the design of next-generation hypersonic vehicles.”

Hypersonic speed is defined as faster than five times the speed of sound or greater than Mach 5. When something is flying that fast, the air moving around a flying object will chemically decompose. Some points behind the shockwave created by the vehicle are hotter than the surface of the sun. This strange chemical environment causes whatever is traveling through it to heat up, and even melt and chemically react with the air.

Mueschke has researched the hypersonic environment extensively at SwRI using the Institute’s two-stage light gas gun system, which simulates hypersonic flight conditions and allows researchers to image objects in hypersonic flight.

“When we launch an object at hypersonic speeds, the air around it begins to break down,” Mueschke said. “The molecules in the air, like nitrogen and oxygen, break apart and sometimes form new compounds. The puzzle pieces start rearranging them-selves.”

By pointing a laser at just the right wavelength at the air flow around a hypersonic ve-hicle, certain molecules absorb the light briefly and then emit it in different colors, a process known as laser-induced fluorescence.

“That process helps us understand other things,” Mueschke said. “For example, the molecules take a little while to expel all of that light, and during that time, they move a little. If we take image after image of this glowing field of light, we can determine how fast the molecules are moving.”

Determining the velocity of the air around the hypersonic object is significant because so little is known about that true hypersonic flight environment. Intrusive instruments that can measure air velocity are useless because they interfere with the airflow and flight environment.

“We need to find a way to make very detailed measurements of what exactly is going on without getting in the way,” Mueschke said. “For the scale of the objects we’re fly-ing, all the most relevant action is happening within a millimeter of the surface of the object as it’s in motion. Everything we’re looking for is happening in that space.”

From there, Mueschke and Combs hope to measure the environment’s pressure, tem-perature and density, eventually leading to a truly representative picture of the hyper-sonic flight environment, which is extremely difficult to measure.

“When we talk hypersonic flight, this generally refers to speeds faster than five times the speed of sound, which is roughly 4,000 mph,” Combs said. “At this speed it would take less than an hour to fly from New York to Los Angeles, and you could get from San Antonio to just about anywhere in the continental US in less than 30 minutes. There’s potential to truly revolutionize how we get from place to place. Add in the fact that all spacecraft return to Earth at hypersonic speeds, along with the obvious defense applications, and you can see why hypersonics is a particularly hot topic right now.”


Mueschke and Combs will make their initial measurements at Combs’s laboratory at UTSA, which will soon include a Mach 7 Ludwieg Tube, a facility that can mimic some conditions of hypersonic flight. In later stages, the project will move to SwRI’s two-stage light gas gun system, which more closely simulates the hypersonic flight envi-ronment.

SwRI’s Executive Office and UTSA’s Office of the Vice President for Research, Econom-ic Development, and Knowledge Enterprise sponsor the CONNECT program, which offers grant opportunities to enhance greater scientific collaboration between the two institutions.

For more information, visit

Release url:!&utm_medium=Distribution&utm_campaign=Hypersonics-PR

Client service link:!&utm_medium=SwRI&utm_campaign=Hypersonics-PR

Similar Articles



Please enter your comment!
Please enter your name here

Most Popular

Archaeology: Cooling of Earth caused by eruptions, not meteors

IMAGE: Workers excavating Hall's Cave in Central Texas ...

Nanotechnology: Sharing a secret…the quantum way

IMAGE: An artistic impression sharing a secret using structured...

Medicine: Insight on novel genetic approaches to metabolic liver diseases

DETROIT - Diabetes, obesity and nonalcoholic fatty liver disease (NAFLD) are all common diseases that can lead to serious health implications. NAFLD affects over...

Diseases: Targetable biological mechanisms implicated in emergent psychiatric conditions associated with SARS-CoV-2

What The Viewpoint Says: Targetable biological mechanisms implicated in emergent psychiatric conditions associated with SARS-CoV-2 infection are discussed in this Viewpoint. Authors: Teodor T. Postolache, M.D., of...

Science: Policies to mitigate wildfire impacts have public health implications, amplified amid COVID

As the western United States enters the 2020 wildfire season with anticipated above normal significant fire potential, a new report from Physicians, Scientists,...

Climate Change: Texas cave sediment upends meteorite explanation for global cooling

IMAGE: Archaeologic excavations at Hall's Cave exposed sediments for...