Gurzhi effect

Last updated October 05, 2024

The Gurzhi effect was theoretically predicted^[1]^[2] by Radii Gurzhi in 1963, and it consists of decreasing of electric resistance $R$ of a finite size conductor with increasing of its temperature $T$ (i.e. the situation $dR/dT<0$ 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 $l_{lost}=\min\{l_{boundary},l_{V}\}$ — a mean free path corresponding to the momentum loss from the electrons+phonons system $R\propto {\frac {1}{l_{lost}}},$ where $l_{boundary}$ is the average distance which electron pass between two consecutive interactions with a boundary, and $l_{V}$ 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 $l_{ee}\gg d$ , $l_{lost}\approx l_{boundary}\approx d$ , where $d$ is a width of the conductor, $l_{ee}$ 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 $l_{ee}\approx l_{ep}$ , where $l_{ep}\propto T^{-5}$ is a mean free path corresponding to the electron-phonon collisions. Also we assume $d\ll l_{V}$ . Thus the resistance for lowest temperatures is a constant $R\propto d^{-1}$ (see the picture). The Gurzhi effect appears when the temperature is increased to have $l_{ee}\ll d$ . In this regime the electron diffusive length between two consecutive interactions with the boundary can be considered as momentum loss free path: $l_{lost}\approx l_{boundary}\approx d^{2}/l_{ee}$ , and the resistance is proportional to $R\propto l_{ee}(T)/d^{2}\propto T^{-5}d^{-2}$ , and thus we have a negative derivative $dR/dT<0$ . Therefore, Gurzhi effect can be observed when $l_{ee}\ll d\ll d^{2}/l_{ee}\ll l_{V}$ .

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 $d$ . 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 $d$ 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.

Related Research Articles

Superfluid helium-4 is the superfluid form of helium-4, an isotope of the element helium. A superfluid is a state of matter in which matter behaves like a fluid with zero viscosity. The substance, which resembles other liquids such as helium I, flows without friction past any surface, which allows it to continue to circulate over obstructions and through pores in containers which hold it, subject only to its own inertia.

<span class="mw-page-title-main">Kondo effect</span> Physical phenomenon due to impurities

In physics, the Kondo effect describes the scattering of conduction electrons in a metal due to magnetic impurities, resulting in a characteristic change i.e. a minimum in electrical resistivity with temperature. The cause of the effect was first explained by Jun Kondo, who applied third-order perturbation theory to the problem to account for scattering of s-orbital conduction electrons off d-orbital electrons localized at impurities. Kondo's calculation predicted that the scattering rate and the resulting part of the resistivity should increase logarithmically as the temperature approaches 0 K. Extended to a lattice of magnetic impurities, the Kondo effect likely explains the formation of heavy fermions and Kondo insulators in intermetallic compounds, especially those involving rare earth elements such as cerium, praseodymium, and ytterbium, and actinide elements such as uranium. The Kondo effect has also been observed in quantum dot systems.

<span class="mw-page-title-main">Polaron</span> Quasiparticle in condensed matter physics

A polaron is a quasiparticle used in condensed matter physics to understand the interactions between electrons and atoms in a solid material. The polaron concept was proposed by Lev Landau in 1933 and Solomon Pekar in 1946 to describe an electron moving in a dielectric crystal where the atoms displace from their equilibrium positions to effectively screen the charge of an electron, known as a phonon cloud. This lowers the electron mobility and increases the electron's effective mass.

Tunnel magnetoresistance (TMR) is a magnetoresistive effect that occurs in a magnetic tunnel junction (MTJ), which is a component consisting of two ferromagnets separated by a thin insulator. If the insulating layer is thin enough, electrons can tunnel from one ferromagnet into the other. Since this process is forbidden in classical physics, the tunnel magnetoresistance is a strictly quantum mechanical phenomenon, and lies in the study of spintronics.

<span class="mw-page-title-main">Magnon</span> Spin 1 quasiparticle; quantum of a spin wave

A magnon is a quasiparticle, a collective excitation of the spin structure of an electron in a crystal lattice. In the equivalent wave picture of quantum mechanics, a magnon can be viewed as a quantized spin wave. Magnons carry a fixed amount of energy and lattice momentum, and are spin-1, indicating they obey boson behavior.

Jellium, also known as the uniform electron gas (UEG) or homogeneous electron gas (HEG), is a quantum mechanical model of interacting electrons in a solid where the positive charges are assumed to be uniformly distributed in space; the electron density is a uniform quantity as well in space. This model allows one to focus on the effects in solids that occur due to the quantum nature of electrons and their mutual repulsive interactions without explicit introduction of the atomic lattice and structure making up a real material. Jellium is often used in solid-state physics as a simple model of delocalized electrons in a metal, where it can qualitatively reproduce features of real metals such as screening, plasmons, Wigner crystallization and Friedel oscillations.

In mesoscopic physics, ballistic conduction is the unimpeded flow of charge carriers, or energy-carrying particles, over relatively long distances in a material. In general, the resistivity of a material exists because an electron, while moving inside a medium, is scattered by impurities, defects, thermal fluctuations of ions in a crystalline solid, or, generally, by any freely-moving atom/molecule composing a gas or liquid. Without scattering, electrons simply obey Newton's second law of motion at non-relativistic speeds.

A two-dimensional electron gas (2DEG) is a scientific model in solid-state physics. It is an electron gas that is free to move in two dimensions, but tightly confined in the third. This tight confinement leads to quantized energy levels for motion in the third direction, which can then be ignored for most problems. Thus the electrons appear to be a 2D sheet embedded in a 3D world. The analogous construct of holes is called a two-dimensional hole gas (2DHG), and such systems have many useful and interesting properties.

A quantum point contact (QPC) is a narrow constriction between two wide electrically conducting regions, of a width comparable to the electronic wavelength.

The spin Hall effect (SHE) is a transport phenomenon predicted by Russian physicists Mikhail I. Dyakonov and Vladimir I. Perel in 1971. It consists of the appearance of spin accumulation on the lateral surfaces of an electric current-carrying sample, the signs of the spin directions being opposite on the opposing boundaries. In a cylindrical wire, the current-induced surface spins will wind around the wire. When the current direction is reversed, the directions of spin orientation is also reversed.

A charge density wave (CDW) is an ordered quantum fluid of electrons in a linear chain compound or layered crystal. The electrons within a CDW form a standing wave pattern and sometimes collectively carry an electric current. The electrons in such a CDW, like those in a superconductor, can flow through a linear chain compound en masse, in a highly correlated fashion. Unlike a superconductor, however, the electric CDW current often flows in a jerky fashion, much like water dripping from a faucet due to its electrostatic properties. In a CDW, the combined effects of pinning and electrostatic interactions likely play critical roles in the CDW current's jerky behavior, as discussed in sections 4 & 5 below.

In condensed matter physics, second sound is a quantum mechanical phenomenon in which heat transfer occurs by wave-like motion, rather than by the more usual mechanism of diffusion. Its presence leads to a very high thermal conductivity. It is known as "second sound" because the wave motion of entropy and temperature is similar to the propagation of pressure waves in air (sound). The phenomenon of second sound was first described by Lev Landau in 1941.

A composite fermion is the topological bound state of an electron and an even number of quantized vortices, sometimes visually pictured as the bound state of an electron and, attached, an even number of magnetic flux quanta. Composite fermions were originally envisioned in the context of the fractional quantum Hall effect, but subsequently took on a life of their own, exhibiting many other consequences and phenomena.

The transport of heat in solids involves both electrons and vibrations of the atoms (phonons). When the solid is perfectly ordered over hundreds of thousands of atoms, this transport obeys established physics. However, when the size of the ordered regions decreases new physics can arise, thermal transport in nanostructures. In some cases heat transport is more effective, in others it is not.

Phonons can scatter through several mechanisms as they travel through the material. These scattering mechanisms are: Umklapp phonon-phonon scattering, phonon-impurity scattering, phonon-electron scattering, and phonon-boundary scattering. Each scattering mechanism can be characterised by a relaxation rate 1/ $which is the inverse of the corresponding relaxation time.$

In quantum mechanics, orbital magnetization, M_orb, refers to the magnetization induced by orbital motion of charged particles, usually electrons in solids. The term "orbital" distinguishes it from the contribution of spin degrees of freedom, M_spin, to the total magnetization. A nonzero orbital magnetization requires broken time-reversal symmetry, which can occur spontaneously in ferromagnetic and ferrimagnetic materials, or can be induced in a non-magnetic material by an applied magnetic field.

Heat transfer physics describes the kinetics of energy storage, transport, and energy transformation by principal energy carriers: phonons, electrons, fluid particles, and photons. Heat is thermal energy stored in temperature-dependent motion of particles including electrons, atomic nuclei, individual atoms, and molecules. Heat is transferred to and from matter by the principal energy carriers. The state of energy stored within matter, or transported by the carriers, is described by a combination of classical and quantum statistical mechanics. The energy is different made (converted) among various carriers. The heat transfer processes are governed by the rates at which various related physical phenomena occur, such as the rate of particle collisions in classical mechanics. These various states and kinetics determine the heat transfer, i.e., the net rate of energy storage or transport. Governing these process from the atomic level to macroscale are the laws of thermodynamics, including conservation of energy.

<span class="mw-page-title-main">Samarium hexaboride</span> Chemical compound

Samarium hexaboride (SmB₆) is an intermediate-valence compound where samarium is present both as Sm²⁺ and Sm³⁺ ions at the ratio 3:7. It is a Kondo insulator having a metallic surface state.

Electric dipole spin resonance (EDSR) is a method to control the magnetic moments inside a material using quantum mechanical effects like the spin–orbit interaction. Mainly, EDSR allows to flip the orientation of the magnetic moments through the use of electromagnetic radiation at resonant frequencies. EDSR was first proposed by Emmanuel Rashba.

Graphene is a semimetal whose conduction and valence bands meet at the Dirac points, which are six locations in momentum space, the vertices of its hexagonal Brillouin zone, divided into two non-equivalent sets of three points. The two sets are labeled K and K′. The sets give graphene a valley degeneracy of gv = 2. By contrast, for traditional semiconductors the primary point of interest is generally Γ, where momentum is zero. Four electronic properties separate it from other condensed matter systems.

References

↑ Gurzhi, R. N. (1963). "Minimum of resistance in impurity-free conductors". J Exp Theor Phys. 17: 521.
↑ Gurzhi, R. N. (1968). "HYDRODYNAMIC EFFECTS IN SOLIDS AT LOW TEMPERATURE". Soviet Physics Uspekhi. 11 (2): 255–270. doi:10.1070/PU1968v011n02ABEH003815.
↑ 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.
↑ 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.
↑ 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.
↑ 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 .
↑ 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 .
↑ 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 .
↑ 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.
↑ 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.
↑ 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.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[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] 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 .

[:0-9] 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.

[:1-10] 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.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]