73.21.Fg Quantum wells
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L.V. Kulik, A.V. Gorbunov et al “Spin excitations in two-dimensional electron gas, their relaxation, photoexcitation and detection methods, and the role of Coulomb correlations” Phys. Usp. 62 865–891 (2019)
71.35.Lk, 73.21.Fg, 78.67.De (all)
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P.V. Ratnikov, A.P. Silin “Two-dimensional graphene electronics: current status and prospects” Phys. Usp. 61 1139–1174 (2018)
68.65.Cd, 68.65.Pq, 73.21.Fg, 73.40.Gk, 73.50.−h, 85.30.Tv, 85.40.−e, 85.60.−q, 85.65.+h (all)
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Yu.E. Lozovik “New effects in and the control of the exciton system in quasi-two-dimensional structures” Phys. Usp. 61 1094–1099 (2018)
03.75.Nt, 67.80.−s, 73.21.Fg, 71.35.−y, 71.45.−d (all)
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P.S. Kop’ev, I.N. Ural’tsev “The energy spectrum of Coulomb states in a quantum well” Sov. Phys. Usp. 32 280–281 (1989)
78.67.De, 78.55.Cr, 73.21.Fg (all)
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B.A. Volkov, O.A. Pankratov “Inverted contact in semiconductors—a new inhomogeneous structure with a twodimensional gas of zero-mass electrons” Sov. Phys. Usp. 29 579–581 (1986)
71.20.Nr, 73.21.Fg (all)
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