The origin of the universe started with the Big Bang, but how the supernova explosion ignited has long been a mystery—until now.
University of Central Florida

© Karen Norum, UCF Office of Research | Jessica Chambers, a doctoral student in the University of Central Florida's Department of Mechanical and Aerospace Engineering, and Kareem Ahmed, an assistant professor in UCF's Department of Mechanical and Aerospace Engineering, set up the turbulent shock tube they used to help uncover the mechanisms that could have caused the Big Bang.
In a new paper appearing today in Science magazine, researchers detailed the mechanisms that could cause the explosion, which is key for the models that scientists use to understand the origin of the universe.
"We defined the critical criteria where we can drive a flame to self-generate its own turbulence, spontaneously accelerate, and transition into detonation," says Kareem Ahmed, an assistant professor in UCF's Department of Mechanical and Aerospace Engineering and co-author of the study.
"We're using the turbulence to enhance the mixing of the reactions to the point where it transitions into this violent reaction and essentially leads to supernovas, which is exploding stars in simple terms," Ahmed says. "We're taking a simplified flame to where it's reacting at five times the ."
The researcher uncovered the criteria for creating a Big Bang-type  while exploring methods for hypersonic jet propulsion.
"We explore these supersonic reactions for propulsion, and as a result of that, we came across this mechanism that looked very interesting," he said. "When we started to dig deeper, we realized that this is relatable to something as profound as the origin of the universe."
The key is applying the right amount of turbulence and mixing to an unconfined flame until it becomes self-perpetuating, at which point the flame begins to burn the ingested energy leading to a Mach 5 hypersonic .
Applications for the discovery could include faster air and  and improved power generation, including reactions that generate zero emissions as all of the products used in the combustion are converted into energy. The discovery was made by using a unique turbulent shock tube that allowed explosions to be created and analyzed in a contained environment. Ultra-high-speed lasers and cameras were used to measure the explosions and help indicate what factors were needed to reach the point where a  becomes a hypersonic, violent reaction.


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Turbulence-driven spontaneous shock formation in a thermonuclear flame. Credit: Alexei Y. Poludnenko, Jessica Chambers, Kareem Ahmed, Vadim N. Gamezo, Brian D. Taylor, Rendering by the U.S. Department of Defense High-Performance Computing Modernization Program Data Analysis and Assessment Center

UCF's Propulsion and Energy Research Laboratory, where the research was performed, has the only turbulent shock tube for testing hypersonic reactions in the nation.

This article was originally published by the University of Central Florida.
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