Gurzhi effect

The Gurzhi effect was theoretically predicted^[1][2] by Radii Gurzhi in 1963, and it consists of decreasing of electric resistance ${\displaystyle R}$ of a finite size conductor with increasing of its temperature ${\displaystyle T}$ (i.e. the situation ${\displaystyle dR/dT<0}$ for some temperature interval). Gurzhi effect usually being considered as the evidence of electron hydrodynamic transport^{[3][4][5][6][7][8]} in conducting media. The mechanism of Gurzhi effect is the following. The value of the resistance of the conductor is inverse to the ${\displaystyle l_{lost}=\min\{l_{boundary},l_{V}\}}$ — a mean free path corresponding to the momentum loss from the electrons+phonons system

Gurzhi effect

The different transport regimes are shown. Blue circle is the electron travelling in a conductor with the width d. Red stars are corresponded to the collisions with lost of total momentum of the electron system.

$${\displaystyle R\propto {\frac {1}{l_{lost}}},}$$

where ${\displaystyle l_{boundary}}$ is the average distance which electron pass between two consecutive interactions with a boundary, and ${\displaystyle l_{V}}$ is a mean free path corresponding to other possibilities of momentum loss. The electron reflection from the boundary is assumed to be diffusive.

When temperature is low we have ballistic transport with ${\displaystyle l_{ee}\gg d}$, ${\displaystyle l_{lost}\approx l_{boundary}\approx d}$, where ${\displaystyle d}$ is a width of the conductor, ${\displaystyle l_{ee}}$is a mean free path corresponding to effective normal electron-electron collisions (i.e. collisions without total electrons+phonons momentum loss). For low temperatures phonon emitted by electron quickly interacts with another electron without loss of total electron+phonons momentum and ${\displaystyle l_{ee}\approx l_{ep}}$, where ${\displaystyle l_{ep}\propto T^{-5}}$is a mean free path corresponding to the electron-phonon collisions. Also we assume ${\displaystyle d\ll l_{V}}$. Thus the resistance for lowest temperatures is a constant ${\displaystyle R\propto d^{-1}}$(see the picture). The Gurzhi effect appears when the temperature is increased to have ${\displaystyle l_{ee}\ll d}$ . In this regime the electron diffusive length between two consecutive interactions with the boundary can be considered as momentum loss free path: ${\displaystyle l_{lost}\approx l_{boundary}\approx d^{2}/l_{ee}}$, and the resistance is proportional to ${\displaystyle R\propto l_{ee}(T)/d^{2}\propto T^{-5}d^{-2}}$, and thus we have a negative derivative ${\displaystyle dR/dT<0}$ . Therefore, Gurzhi effect can be observed when ${\displaystyle l_{ee}\ll d\ll d^{2}/l_{ee}\ll l_{V}}$.

Gurzhi effect corresponds to unusual situation when electrical resistance depends on a frequency of normal collisions. As one can see this effect appears due to the presence of a boundaries with finite characteristic size ${\displaystyle d}$. Later Gurzhi's group discovered a special role of electron hydrodynamics in a spin transport.^[9][10] In such a case magnetic inhomogeneity plays role of a "boundary" with spin-diffusion length^[11] as a characteristic size instead of ${\displaystyle d}$ as before. This magnetic inhomogeneity stops electrons of the one spin component which becomes an effective scatterers for electrons of another spin component. In this case magnetoresistance of a conductor depends on the frequency of normal electron-electron collisions as well as in the Gurzhi effect.

References

1. Gurzhi, R. N. (1963). "Minimum of resistance in impurity-free conductors". J Exp Theor Phys. 17: 521.
2. Gurzhi, R. N. (1968). "HYDRODYNAMIC EFFECTS IN SOLIDS AT LOW TEMPERATURE". Soviet Physics Uspekhi. 11 (2): 255–270. doi:10.1070/PU1968v011n02ABEH003815.
3. Yu, Z. -Z.; Haerle, M.; Zwart, J. W.; Bass, J.; Pratt, W. P.; Schroeder, P. A. (1984). "Negative Temperature Derivative of Resistivity in Thin Potassium Samples: The Gurzhi Effect?". Phys. Rev. Lett. 52 (5): 368–371. doi:10.1103/PhysRevLett.52.368.
4. de Jong, M. J. M.; Molenkamp, L. W. (1995). "Hydrodynamic electron flow in high-mobility wires". Phys. Rev. B. 51 (19): 13389–13402. arXiv:cond-mat/9411067. doi:10.1103/PhysRevB.51.13389.
5. Alekseev, P. S. (2016). "Negative Magnetoresistance in Viscous Flow of Two-Dimensional Electrons". Phys. Rev. Lett. 117 (16): 166601. arXiv:1603.04587. doi:10.1103/PhysRevLett.117.166601.
6. Narozhny, Boris N.; Gornyi, Igor V.; Mirlin, Alexander D.; Schmalian, Jörg (2017). "Hydrodynamic Approach to Electronic Transport in Graphene". Annalen der Physik. 529 (11): 1700043. arXiv:1704.03494. doi:10.1002/andp.201700043.
7. Moll, Philip J. W.; Kushwaha, Pallavi; Nandi, Nabhanila; Schmidt, Burkhard; Mackenzie, Andrew P. (2016). "Evidence for hydrodynamic electron flow in PdCoO2". Science. 351 (6277): 1061–1064. doi:10.1126/science.aac8385. hdl:10023/8262.
8. Scaffidi, Thomas; Nandi, Nabhanila; Schmidt, Burkhard; Mackenzie, Andrew P.; Moore, Joel E. (2017). "Hydrodynamic Electron Flow and Hall Viscosity". Phys. Rev. Lett. 118 (22): 226601. doi:10.1103/PhysRevLett.118.226601. hdl:10023/11223.
9. Gurzhi, R. N.; Kalinenko, A. N.; Kopeliovich, A. I.; Pyshkin, P. V.; Yanovsky, A. V. (2006). "Dynamics of a spin-polarized electron liquid: Spin oscillations with a low decay". Phys. Rev. B. 73 (15): 153204. arXiv:1109.1872. doi:10.1103/PhysRevB.73.153204.
10. Gurzhi, R. N.; Kalinenko, A. N.; Kopeliovich, A. I.; Pyshkin, P. V.; Yanovsky, A. V. (2011). "Electrical resistance of spatially varying magnetic interfaces. The role of normal scattering". Low Temperature Physics. 37 (2): 149–156. arXiv:1109.0555. doi:10.1063/1.3556662.
11. Bass, J.; Pratt, W. P. (2007). "Spin-diffusion lengths in metals and alloys, and spin-flipping at metal/metal interfaces: an experimentalist's critical review". Journal of Physics: Condensed Matter. 19: 183201. arXiv:cond-mat/0610085. doi:10.1088/0953-8984/19/18/183201.