Spontaneous Valley Polarization of Itinerant Electrons

Hossain, Md. Shafayat; K., M.; Villegas-Rosales, K. A.; Chung, Yoon Jang; Pfeiffer, L. N.; West, K. W.; Baldwin, K. W.; Shayegan, M.

doi:10.1103/physrevlett.127.116601

Cited by 24 publications

(5 citation statements)

References 42 publications

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“…The effect of electron-electron and electron-phonon interaction on valley polarization was examined recently. In an itinerant electron system, Hossain et al [140] demonstrated theoretically that the electron-electron interaction prefers singlevalley occupancy of electrons below a critical density. Consequently, one can switch the valley polarization from 0 to 1 by a small reduction in density and thus design a valleytronic transistor device.…”

Section: Recent Progress Of Valleytronics Beyond Graphenementioning

confidence: 99%

Valley filtering and valley-polarized collective modes in bulk graphene monolayers

Zheng 郑,

Zhai 翟

2024

Chinese Phys. B

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The presence of two sublattices in hexagonal graphene brings two energetically degenerate extremes in the conduction and valence band, which are identified by the valley quantum number. Recently, this valley degree of freedom has been suggested to encode and process information, which develops a new carbon-based electronics named graphene valleytronics. In this topical review, we present and discuss valley-related transport properties in bulk graphene monolayers, which are due to strain-induced pseudomagnetic fields and associated vector potential, sublattice-stagger potential, and the valley-Zeeman effect. These valley-related interactions can be utilized to obtain valley filtering, valley spatial separation, valley-resolved guiding modes, and valley-polarized collective modes such as edge or surface plasmons. The present challenges and the perspectives on graphene valleytronics are also provided in this review.

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Section: Recent Progress Of Valleytronics Beyond Graphenementioning

confidence: 99%

Valley filtering and valley-polarized collective modes in bulk graphene monolayers

Zheng 郑,

Zhai 翟

2024

Chinese Phys. B

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“…the prominent K and −K valleys in 2D hexagonal materials) [4,5]. Up to now, several external strategies have been experimentally confirmed to be effective for eliminating the valley degeneracies, such as optical pumping [6,7], magnetic doping [8,9], magnetic proximity [10], external magnetic field [11][12][13], and electric field [14][15][16]. However, these approaches have various insurmountable drawbacks (e.g.…”

Section: Introductionmentioning

confidence: 99%

2D electrene LaH₂ monolayer: an ideal ferrovalley direct semiconductor with room-temperature ferromagnetic stability

Shi

Jia

Cai

et al. 2022

J. Phys.: Condens. Matter

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In developing nonvolatile valleytronic devices, ferromagnetic (FM) ferrovalley semiconductors are critically needed due to the existence of spontaneous valley polarization. At present, however, the known real materials have various drawbacks towards practical applications, including the in-plane FM ground state, low Curie temperature (T C), small valley polarization, narrow energy window with clean polarized valley, and indirect bandgap. From first-principles calculations, here we predict an ideal ferrovalley semiconductor, honeycomb LaH2 monolayer (ML), whose intrinsic properties can overcome all these shortcomings. We demonstrate that LaH2 ML, having satisfied structural stability, is a FM half-semiconducting electrene (La3+2H − · e−) with its magnetic moments localized at the lattice interstitial sites rather than La atoms. At the same time, LaH2 ML holds the following desired attributes: a robust out-of-plane FM ground state with a high T C (334 K), a sizable valley polarization (166 meV), a wide energy window (137 meV) harboring clean singlevalley carriers, and a direct bandgap. These results identify a much needed ideal ferrovalley semiconductor candidate, holding the promising application potential in valleytronics and spintronics devices.

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“…Here there is no uniaxial strain applied so that the two inplane valleys (X and Y), with their major axes along [100] and [010], are equally occupied at high densities; R [100] and R [010] are essentially equal and the 2DES is isotropic. As n is lowered below 6.3 (r s 20), all the electrons suddenly transfer to the Y valley, leading to R polarization, which is akin to Bloch spin ferromagnetism transition, has been discussed in detail elsewhere [43]; see also [58]. At lower densities, when n 3.2 (r s 28), the 2DES turns insulating as signaled by the temperature dependence of R [100] and R [010] at low temperatures; see Figs.…”

mentioning

confidence: 96%

“…Strong electron-electron interaction in clean twodimensional electron systems (2DESs) leads to a plethora of many-body phases such as fractional quantum Hall liquid [1], Wigner solid (WS) [2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21], and correlated magnetism [16,[22][23][24][25][26][27][28][29]. Anisotropy introduces a new flavor to the interaction phenomena and triggers yet another set of unexpected correlated phases [30][31][32][33][34][35][36][37][38][39][40][41][42][43], such as nematic quantum Hall states [32, 34-36, 40, 42]. A tantalizing example of Fermi sea anisotropy induced many-body states is a theoretically proposed anisotropic WS at zero magnetic field [30].…”

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confidence: 99%

Anisotropic Two-Dimensional Disordered Wigner Solid

Hossain

Villegas-Rosales

et al. 2022

Phys. Rev. Lett.

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The interplay between the Fermi sea anisotropy, electron-electron interaction, and localization phenomena can give rise to exotic many-body phases. An exciting example is an anisotropic two-dimensional (2D) Wigner solid (WS), where electrons form an ordered array with an anisotropic lattice structure. Such a state has eluded experiments up to now as its realization is extremely demanding: First, a WS entails very low densities where the Coulomb interaction dominates over the kinetic (Fermi) energy. Attaining such low densities while keeping the disorder low is very challenging. Second, the low-density requirement has to be fulfilled in a material that hosts an anisotropic Fermi sea. Here, we report transport measurements in a clean (low-disorder) 2D electron system with anisotropic effective mass and Fermi sea. The data reveal that at extremely low electron densities, when the rs parameter, the ratio of the Coulomb to the Fermi energy, exceeds 38, the current-voltage characteristics become strongly nonlinear at small dc biases. Several key features of the nonlinear characteristics, including their anisotropic voltage thresholds, are consistent with the formation of a disordered, anisotropic WS pinned by the ubiquitous disorder potential.

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Spontaneous Valley Polarization of Itinerant Electrons

Cited by 24 publications

References 42 publications

Valley filtering and valley-polarized collective modes in bulk graphene monolayers

Valley filtering and valley-polarized collective modes in bulk graphene monolayers

2D electrene LaH₂ monolayer: an ideal ferrovalley direct semiconductor with room-temperature ferromagnetic stability

Anisotropic Two-Dimensional Disordered Wigner Solid

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Spontaneous Valley Polarization of Itinerant Electrons

Cited by 24 publications

References 42 publications

Valley filtering and valley-polarized collective modes in bulk graphene monolayers

Valley filtering and valley-polarized collective modes in bulk graphene monolayers

2D electrene LaH2 monolayer: an ideal ferrovalley direct semiconductor with room-temperature ferromagnetic stability

Anisotropic Two-Dimensional Disordered Wigner Solid

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Product

Resources

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2D electrene LaH₂ monolayer: an ideal ferrovalley direct semiconductor with room-temperature ferromagnetic stability