We discuss the directional motion of an elastic three-sphere micromachine in
which the spheres are in equilibrium with independent heat baths having
different temperatures. Even in the absence of prescribed motion of springs,
such a micromachine can gain net motion purely because of thermal fluctuations.
A relation connecting the average velocity and the temperatures of the spheres
is analytically obtained. This velocity can also be expressed in terms of the
average heat flows in the steady state. Our model suggests a new mechanism for
the locomotion of micromachines in nonequilibrium biological systems.Comment: 5 pages, 2 figure
We discuss the non-equilibrium statistical mechanics of a thermally driven micromachine consisting of three spheres and two harmonic springs [Y. Hosaka et al., J. Phys. Soc. Jpn. 86 (2017)]. We obtain the non-equilibrium steady state probability distribution function of such a micromachine and calculate its probability flux in the corresponding mode space. The resulting probability flux can be expressed in terms of a frequency matrix that is used to distinguish between a non-equilibrium steady state and a thermal equilibrium state satisfying detailed balance. We analytically show that the probability flux of a micromachine is proportional to the temperature difference between the first and the third spheres when the friction coefficients are all identical. The scale of non-equilibrium of a micromachine can quantitatively be characterized by the flux rotor. We obtain a linear relation between the flux rotor and the average velocity of a thermally driven micromachine that can undergo a directed motion in a viscous fluid.
We investigate the statistical properties of fluctuations in active systems that are governed by non-symmetric responses. Both an underdamped Langevin system with an odd resistance tensor and an overdamped Langevin system with an odd elastic tensor are studied. For a system in thermal equilibrium, the time-correlation functions should satisfy time-reversal symmetry and the anti-symmetric parts of the correlation functions should vanish. For the odd Langevin systems, however, we find that the anti-symmetric parts of the time-correlation functions can exist and that they are proportional to either the odd resistance coefficient or the odd elastic constant. This means that the time-reversal invariance of the correlation functions is broken due to the presence of odd responses in active systems. Using the short-time asymptotic expressions of the time-correlation functions, one can estimate an odd elastic constant of an active material such as an enzyme or a motor protein.
We investigate the statistical properties of fluctuations in active systems that are governed by non-symmetric responses. Both an underdamped Langevin system with an odd resistance tensor and an overdamped Langevin system with an odd elastic tensor are studied. For a system in thermal equilibrium, the time-correlation functions should satisfy time-reversal symmetry and the anti-symmetric parts of the correlation functions should vanish. For the odd Langevin systems, however, we find that the anti-symmetric parts of the time-correlation functions can exist and that they are proportional to either the odd resistance coefficient or the odd elastic constant. This means that the time-reversal invariance of the correlation functions is broken due to the presence of odd responses in active systems. Using the short-time asymptotic expressions of the time-correlation functions, one can estimate an odd elastic constant of an active material such as an enzyme or a motor protein.
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