Researchers from the Great St.Petersburg Polytechnic University (SPbPU) have discovered and theoretically explained a new physical effect: amplitude of mechanical vibrations can grow without external influence.
The scientific group offered their explanation on how to eliminate the Fermi-Pasta-Ulam-Tsingou paradox. The scientists of SPbPU explained it using a simple example: to rock a swing, you have to keep pushing it. It is generally believed that it is impossible to achieve oscillatory resonance without constant external influence. However, the scientific group discovered a new physical phenomenon of "ballistic resonance", where mechanical oscillations can be excited only due to internal thermal resources of the system.
The experimental work of researchers from all around the world demonstrated, that heat spreads at abnormally high speeds at nano and micro levels in ultrapure crystalline materials. This phenomenon is called ballistic heat conductivity. The scientific group supervised by the corresponding member of Russian Academy of Sciences Anton Krivtsov, derived the equations describing this phenomenon and made significant progress in the overall understanding of thermal processes at the micro-level. In the study published in Physical Review E researchers considered the system behavior at the initial periodic distribution of temperature in the crystal material. The discovered phenomenon describes that the process of heat equilibration leads to mechanical vibrations with an amplitude that grows with time. The effect is called ballistic resonance.
These discoveries also provide an opportunity to resolve the paradox of Fermi-Pasta-Ulam-Tsingou. In 1953, a scientific group led by Enrico Fermi carried out a computer experiment that later became famous. Scientists considered the simplest model of oscillations of a chain of particles connected by springs. They assumed that the mechanical movement would gradually fade away, turning into chaotic thermal oscillations. Still, the result was unexpected: the oscillations in the chain first almost decayed, but then revived and reached nearly the initial level. The system came to its initial state, and the cycle repeated itself. The causes of mechanical oscillations from thermal vibrations in the considered system have been the subject of scientific research and disputes for decades.
The amplitude of mechanical vibrations caused by ballistic resonance doesn't increase infinitely, but reaches its maximum; after that it starts gradually decreasing to zero. Eventually, mechanical oscillations fade completely, and the temperature equilibrates in the whole crystal. This process is called thermalization. For physicists, this experiment is vital because a chain of particles connected by springs is a good model of crystal material.
Researchers of the Higher School of Theoretical Mechanics showed that the transition of mechanical energy into heat is irreversible if we consider the process at the finite temperature. The theoretical approach proposed by the SPbPU scientists demonstrates a new approach to how we understand heat and temperature.
In the future the researchers plan to analyze how this can be used in such promising materials as, for example, graphene.
https://phys.org/news/2020-07-scientists-physical-paradox.html
The scientific group offered their explanation on how to eliminate the Fermi-Pasta-Ulam-Tsingou paradox. The scientists of SPbPU explained it using a simple example: to rock a swing, you have to keep pushing it. It is generally believed that it is impossible to achieve oscillatory resonance without constant external influence. However, the scientific group discovered a new physical phenomenon of "ballistic resonance", where mechanical oscillations can be excited only due to internal thermal resources of the system.
The experimental work of researchers from all around the world demonstrated, that heat spreads at abnormally high speeds at nano and micro levels in ultrapure crystalline materials. This phenomenon is called ballistic heat conductivity. The scientific group supervised by the corresponding member of Russian Academy of Sciences Anton Krivtsov, derived the equations describing this phenomenon and made significant progress in the overall understanding of thermal processes at the micro-level. In the study published in Physical Review E researchers considered the system behavior at the initial periodic distribution of temperature in the crystal material. The discovered phenomenon describes that the process of heat equilibration leads to mechanical vibrations with an amplitude that grows with time. The effect is called ballistic resonance.
These discoveries also provide an opportunity to resolve the paradox of Fermi-Pasta-Ulam-Tsingou. In 1953, a scientific group led by Enrico Fermi carried out a computer experiment that later became famous. Scientists considered the simplest model of oscillations of a chain of particles connected by springs. They assumed that the mechanical movement would gradually fade away, turning into chaotic thermal oscillations. Still, the result was unexpected: the oscillations in the chain first almost decayed, but then revived and reached nearly the initial level. The system came to its initial state, and the cycle repeated itself. The causes of mechanical oscillations from thermal vibrations in the considered system have been the subject of scientific research and disputes for decades.
The amplitude of mechanical vibrations caused by ballistic resonance doesn't increase infinitely, but reaches its maximum; after that it starts gradually decreasing to zero. Eventually, mechanical oscillations fade completely, and the temperature equilibrates in the whole crystal. This process is called thermalization. For physicists, this experiment is vital because a chain of particles connected by springs is a good model of crystal material.
Researchers of the Higher School of Theoretical Mechanics showed that the transition of mechanical energy into heat is irreversible if we consider the process at the finite temperature. The theoretical approach proposed by the SPbPU scientists demonstrates a new approach to how we understand heat and temperature.
In the future the researchers plan to analyze how this can be used in such promising materials as, for example, graphene.
https://phys.org/news/2020-07-scientists-physical-paradox.html
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