Gate-tuned quantum Hall states in Dirac semimetal (Cd _{1− x} Zn _x ) ₃ As ₂

Abstract: Electronic structure of quantum-confined Dirac semimetal is elucidated by establishing carrier control techniques in films.

“…Lots of interesting transport properties have been revealed in 3D Dirac semimetals, such as chiral anomaly induced negative magnetoresistance [9,10], Weyl-orbit related quantum oscillations [13,14], Berry's phase π related Aharonov-Bohm effect [15,16], bulksurface interference induced Fano effect [19], etc. Furthermore, the quantum Hall effect (QHE) in Cd 3 As 2 films has been reported recently [20][21][22][23]. For Dirac materials, the quantum Hall plateaus are generally observed at g × ðn þ 1=2Þe 2 =h, where g is the degeneracy and the 1=2 term comes from the Berry's phase π [24].…”

“…However, the quantum Hall plateaus in Cd 3 As 2 were found to be a series of even filling factors υ ¼ 1; 2; 4; 6, where υ ¼ 1 is attributed to the splitting of the lowest Landau level [21,22]. Nishihaya et al attributed the observed QHE to the quantum confinement induced bulk subbands in the thin film with thickness ∼35 nm [20,22]. Schumann et al proposed that the QHE may from the Weyl orbit for the same film thickness ∼35 nm [21].…”

“…Thus, the filling factors can be a series of continuous integer values (both odd and even) or only odd series depending on the top and bottom surface carrier densities [25]. However, the quantum Hall plateaus in Cd 3 As 2 were found to be a series of even filling factors υ ¼ 1; 2; 4; 6, where υ ¼ 1 is attributed to the splitting of the lowest Landau level [21,22]. Nishihaya et al attributed the observed QHE to the quantum confinement induced bulk subbands in the thin film with thickness ∼35 nm [20,22].…”

“…Schumann et al proposed that the QHE may from the Weyl orbit for the same film thickness ∼35 nm [21]. Despite the debate on the mechanism of the QHE, the quantum Hall plateaus at even filling factors g × ne 2 =h with g ∼ 2 indicate the absence of the Berry's phase π or the topological nature [22].…”

Observation of an Odd-Integer Quantum Hall Effect from Topological Surface States in Cd3As2

“…Lots of interesting transport properties have been revealed in 3D Dirac semimetals, such as chiral anomaly induced negative magnetoresistance [9,10], Weyl-orbit related quantum oscillations [13,14], Berry's phase π related Aharonov-Bohm effect [15,16], bulksurface interference induced Fano effect [19], etc. Furthermore, the quantum Hall effect (QHE) in Cd 3 As 2 films has been reported recently [20][21][22][23]. For Dirac materials, the quantum Hall plateaus are generally observed at g × ðn þ 1=2Þe 2 =h, where g is the degeneracy and the 1=2 term comes from the Berry's phase π [24].…”

“…However, the quantum Hall plateaus in Cd 3 As 2 were found to be a series of even filling factors υ ¼ 1; 2; 4; 6, where υ ¼ 1 is attributed to the splitting of the lowest Landau level [21,22]. Nishihaya et al attributed the observed QHE to the quantum confinement induced bulk subbands in the thin film with thickness ∼35 nm [20,22]. Schumann et al proposed that the QHE may from the Weyl orbit for the same film thickness ∼35 nm [21].…”

“…Thus, the filling factors can be a series of continuous integer values (both odd and even) or only odd series depending on the top and bottom surface carrier densities [25]. However, the quantum Hall plateaus in Cd 3 As 2 were found to be a series of even filling factors υ ¼ 1; 2; 4; 6, where υ ¼ 1 is attributed to the splitting of the lowest Landau level [21,22]. Nishihaya et al attributed the observed QHE to the quantum confinement induced bulk subbands in the thin film with thickness ∼35 nm [20,22].…”

“…Schumann et al proposed that the QHE may from the Weyl orbit for the same film thickness ∼35 nm [21]. Despite the debate on the mechanism of the QHE, the quantum Hall plateaus at even filling factors g × ne 2 =h with g ∼ 2 indicate the absence of the Berry's phase π or the topological nature [22].…”

Observation of an Odd-Integer Quantum Hall Effect from Topological Surface States in Cd3As2

“…Gating has already been demonstrated in a previous section on unstrained, semiconducting nanowires. For the much more metallic Weyl semimetal phase in strained nanowires [6], effective gating is still possible with thin wires or with ionic liquid gating, as has been demonstrated in other metallic systems [68][69][70].…”

Growth and Strain Engineering of Trigonal Te for Topological Quantum Phases in Non-Symmorphic Chiral Crystals

Epitaxial Dirac Semimetal Vertical Heterostructures for Advanced Device Architectures