Sennor survives Puerlor-Level heat and radiation, presenting a real-time monitoring method
Creating nuclear energy takes so much energy – excess heat, pressure and radiation – that every part of the argument must be highlighted each time. Naturally, efficient engineering is a difficult task, but researchers continue to find surprising ways to advance Nuclear technology, the latest of which involves a small chip.
In a recent release, researchers at the University of Maine announced new microelectronic sensors that tolerate the radiation levels and high temperatures of a nuclear reactor core. At the same time, the sensor captures real-time data, providing engineers and operators with critical insight into the operation of the reactor.
“Since many advanced reactors are currently under development that work with these heat sources, there is a great demand for sensors that have tested them,” Mauricio Pereira da Cunha, the Central investigator of the project, said when the principal investigator. “The successful development of these sensors will address and alleviate technical barriers that currently prevent the deployment of advanced nuclear reactors.”
Shooting heat
The sensor is intended to sit inside the furnace of reactors for fleiwa, which produces large loads of energy by splitting two heavy molecules. Specifically, researchers hope to install sensors in advanced high-temperature reactors, run on helium gas and contain ceramic materials to efficiently and safely produce nuclear power.
However, these reactors reach higher temperatures than existing sensors can withstand, as their advantages come with “thermal efficiency achieved at higher temperatures,” the researchers said.
The group, on the other hand, had twenty days of mastery of the same nerves. This prompted them to spend the last two years developing and testing a sensor strong enough for the next reactors – and, while they were at it, make a small sensor a handful of its own.
Small chip, big results
In this project, the group created seven sensors, all of which are being tested by the nuclear laboratory at Ohio State University, according to a report from the COMMUNICATION COW office. Each sensor was 100 nanometers thick – about 1,000 times thinner than a strand of hair – and carried electrodes based on an aluminum alloy.
Indeable, all seven sensors “continued to work” and “show no signs of deterioration” despite five days of Helser blasting them at high energy, about 800 degrees Celsius), the report said. Early analysis also revealed that the sensors were resistant to radiation, too.
“In addition to the higher temperatures, we are now exposing these sensors to higher levels, which have the bases of nuclear radiation at the same time,” Luke Doucette, senior research scientist, said at the release. “This adds a whole new dimension of difficulty in terms of what types of hearing aids can survive these conditions and continue to function.”
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