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Reference: “Computational modeling investigation of pulsed high peak power microwaves and the potential for traumatic brain injury” by Amy M. Dagro, Justin W. Wilkerson, Thaddeus P. Thomas, Benjamin T. Kalinosky and Jason A. Payne, 29 October 2021,
Science Advances.

DOI: 10.1126/sciadv.abd8405,Wilkerson and the team used finite element simulations as part of their computational modeling — the same models that have been used to predict traumatic brain injury in car crashes, football impacts, and even explosive blasts on the battlefield. By applying it to a new energy deposition, the microwave, Wilkerson has opened the door for more research to be conducted on the interactions between the biological body and electromagnetic fields and its applications.,“Although the required power densities at work here are orders of magnitude larger than most real-world exposure conditions, they can be achieved with devices meant to emit high-power electromagnetic pulses in military and research applications,” Wilkerson said.,However, there’s no need to worry about everyday exposure to microwaves or radiofrequency levels. Wilkerson’s study included magnitudes of power far greater than anything the average human will be exposed to.,Published in the journal
Science Advances
, Wilkerson’s research revealed that when applying a small temperature increase over a very short amount of time (microseconds), potentially injurious stress waves are created. Imagine all of the microwave energy needed to pop a bag of popcorn condensed into one-millionth of a second and then directed at the brain.,“The microwave heating causes spatially varying, rapid thermal expansion, which then induces mechanical waves that propagate through the brain, like ripples in a pond,” Wilkerson said. “We found that if those waves interact in just the right way at the center of the brain, the conditions are ideal to induce a traumatic brain injury.”,Using computational modeling, the team’s two-simulation approach first calculates the specific absorption rate (SAR) of planar electromagnetic waves on a 3D model of a human body. The SAR values are then used to calculate changes in temperature throughout the head and brain. Those temperature changes are then used to determine how the brain tissue physically alters in response to the high-intensity microwaves.,Justin Wilkerson, assistant professor in the J. Mike Walker ’66 Department of Mechanical Engineering, in collaboration with researchers at the U.S. Army Research Laboratory and the Air Force Research Laboratory, began investigating the effects of high-powered pulsed microwaves on the human body. Most commonly used for rapid cooking, microwaves are a type of electromagnetic radiation that fall between radio and infrared light on the electromagnetic spectrum.,Microwaves are now known to be safe, effective, and efficient thanks to advancements in science, engineering, and technology. However, recent research from Texas A&M University reveals that exposure to certain extremely high-powered microwave and radio frequencies may result in high stresses within the brain.,Contrary to what was once popular belief, microwave ovens don’t cause cancer. It’s a decades-old concern that may evoke an image of a child standing in front of a microwave, peering through the dimly-lit door, only to be told to take a few steps back or they could be sickened by an inexplicable illness or worse — radiation poisoning.,Texas A&M research findings could change the way we view directed energy and traumatic brain injuries.,Microwave ovens are safe and don’t cause cancer, but exposure to certain extremely high-powered microwave and radio frequencies may result in high stresses within the brain.,

Microwave ovens are safe and don’t cause cancer, but exposure to certain extremely high-powered microwave and radio frequencies may result in high stresses within the brain.


Texas A&M research findings could change the way we view directed energy and traumatic brain injuries.

Contrary to what was once popular belief, microwave ovens don’t cause cancer. It’s a decades-old concern that may evoke an image of a child standing in front of a microwave, peering through the dimly-lit door, only to be told to take a few steps back or they could be sickened by an inexplicable illness or worse — radiation poisoning.


Microwaves are now known to be safe, effective, and efficient thanks to advancements in science, engineering, and technology. However, recent research from Texas A&M University reveals that exposure to certain extremely high-powered microwave and radio frequencies may result in high stresses within the brain.

Justin Wilkerson, assistant professor in the J. Mike Walker ’66 Department of Mechanical Engineering, in collaboration with researchers at the U.S. Army Research Laboratory and the Air Force Research Laboratory, began investigating the effects of high-powered pulsed microwaves on the human body. Most commonly used for rapid cooking, microwaves are a type of electromagnetic radiation that fall between radio and infrared light on the electromagnetic spectrum.

Using computational modeling, the team’s two-simulation approach first calculates the specific absorption rate (SAR) of planar electromagnetic waves on a 3D model of a human body. The SAR values are then used to calculate changes in temperature throughout the head and brain. Those temperature changes are then used to determine how the brain tissue physically alters in response to the high-intensity microwaves.


“The microwave heating causes spatially varying, rapid thermal expansion, which then induces mechanical waves that propagate through the brain, like ripples in a pond,” Wilkerson said. “We found that if those waves interact in just the right way at the center of the brain, the conditions are ideal to induce a traumatic brain injury.”

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Published in the journal Science Advances, Wilkerson’s research revealed that when applying a small temperature increase over a very short amount of time (microseconds), potentially injurious stress waves are created. Imagine all of the microwave energy needed to pop a bag of popcorn condensed into one-millionth of a second and then directed at the brain.

However, there’s no need to worry about everyday exposure to microwaves or radiofrequency levels. Wilkerson’s study included magnitudes of power far greater than anything the average human will be exposed to.

“Although the required power densities at work here are orders of magnitude larger than most real-world exposure conditions, they can be achieved with devices meant to emit high-power electromagnetic pulses in military and research applications,” Wilkerson said.


Wilkerson and the team used finite element simulations as part of their computational modeling — the same models that have been used to predict traumatic brain injury in car crashes, football impacts, and even explosive blasts on the battlefield. By applying it to a new energy deposition, the microwave, Wilkerson has opened the door for more research to be conducted on the interactions between the biological body and electromagnetic fields and its applications.

Reference: “Computational modeling investigation of pulsed high peak power microwaves and the potential for traumatic brain injury” by Amy M. Dagro, Justin W. Wilkerson, Thaddeus P. Thomas, Benjamin T. Kalinosky and Jason A. Payne, 29 October 2021, Science Advances.
DOI: 10.1126/sciadv.abd8405


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