Microwave spectroscopy of the low-filling-factor bilayer electron solid in a wide quantum well

Hatke, A. T.; Liu, Y.; Engel, L. W.; Shayegan, M.; Pfeiffer, L. N.; West, K. W.; Baldwin, K. W.

doi:10.1038/ncomms8071

Cited by 17 publications

(14 citation statements)

References 31 publications

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“…Since η of the type-I WS resonance continues to decrease as ν goes from 0.485 toward 1/2, near-full participation of the carriers in the type-II WS resonance is consistent with the observed type-I WS resonance intensity. When ν goes below 0.48 the type-I WS resonance amplitude increases as the electrons solidify into the type-I WS; by ν = 0.4, η ∼ 100% for the type-I WS [26].…”

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confidence: 99%

Microwave spectroscopic observation of a Wigner solid within the ν=1/2 fractional quantum Hall effect

et al. 2017

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confidence: 99%

Microwave spectroscopic observation of a Wigner solid within the ν=1/2 fractional quantum Hall effect

et al. 2017

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“…A Hall bar is fabricated on it, allowing in situ measurements and control of the 2DEG electron concentration . The fused silica spacer is topped by a 100 nm-thick e-beam evaporated Cr-coating, serving simultaneously as upper cavity wall and gate electrode 36,37 . A gate voltage of V can be applied across the Cr-coating–Hall bar junction to tune the electron concentration.…”

Section: Resultsmentioning

confidence: 99%

“…The sample–spacer–magnet assembly is glued by poly(methyl methacrylate) (PMMA) onto a customized Cu printed circuit board (PCB) with a 5 μm Ni and 200 nm Au surface finish. The PCB hosts a coplanar waveguide (CPW) connecting RF Ports 1 and 2 with mini-SMP connectors 36 . By design, the CPW has a 50 impedance with the sample–magnet assembly loaded.…”

Section: Resultsmentioning

confidence: 99%

“…We next seek experimental evidence for the theoretically predicted KMPs specific to our device. The device is inserted into a He-3 cryostat running at 0.5 K. An Agilent E5071C network analyzer (NA) is used to acquire power transmission (Port 1 to 2) and (Port 2 to 1) in the frequency range 300 kHz to 20 GHz 18,36,37 . Our focused frequency range is limited to 1–10 GHz, beyond which the cables and NA suffer high loss and noise, prohibiting acquisition of clear signals.…”

Section: Resultsmentioning

confidence: 99%

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Topological kink plasmons on magnetic-domain boundaries

et al. 2019

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Two-dimensional topological materials bearing time reversal-breaking magnetic fields support protected one-way edge modes. Normally, these edge modes adhere to physical edges where material properties change abruptly. However, even in homogeneous materials, topology still permits a unique form of edge modes – kink modes – residing at the domain boundaries of magnetic fields within the materials. This scenario, despite being predicted in theory, has rarely been demonstrated experimentally. Here, we report our observation of topologically-protected high-frequency kink modes – kink magnetoplasmons (KMPs) – in a GaAs/AlGaAs two-dimensional electron gas (2DEG) system. These KMPs arise at a domain boundary projected from an externally-patterned magnetic field onto a uniform 2DEG. They propagate unidirectionally along the boundary, protected by a difference of gap Chern numbers ($$\pm1$$ ± 1 ) in the two domains. They exhibit large tunability under an applied magnetic field or gate voltage, and clear signatures of nonreciprocity even under weak-coupling to evanescent photons.

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“…It is well established that in very clean 2D systems of charged carriers, at very small ν (ν < ∼ 1/5 for electrons and ν < ∼ 1/3 for holes) the FQHSs give way to IPs which are believed to be Wigner crystal (WC) phases that are pinned by the small but ubiquitous disorder [4][5][6][7][24][25][26][27]. For both 2D electron and hole systems in wide, symmetric GaAs QWs, the charge distribution becomes more bilayer-like with increasing density and the IP sets in at progressively larger ν [22,28,29]. These IPs are believed to be bilayer WC states which, thanks to the additional layer/subband degree of freedom, are stabilized at relatively large ν compared to the single-layer systems.…”

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Observation of an Anisotropic Wigner Crystal

et al. 2016

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We report a new correlated phase of two-dimensional charged carriers in high magnetic fields, manifested by an anisotropic insulating behavior at low temperatures. It appears in a large range of low Landau level fillings 1/3≲ν≲2/3 in hole systems confined to wide GaAs quantum wells when the sample is tilted in magnetic field to an intermediate angle. The parallel field component (B_{∥}) leads to a crossing of the lowest two Landau levels, and an elongated hole wave function in the direction of B_{∥}. Under these conditions, the in-plane resistance exhibits an insulating behavior, with the resistance along B_{∥} about 10 times smaller than the resistance perpendicular to B_{∥}. We interpret this anisotropic insulating phase as a two-component, striped Wigner crystal.

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Microwave spectroscopy of the low-filling-factor bilayer electron solid in a wide quantum well

Cited by 17 publications

References 31 publications

Microwave spectroscopic observation of a Wigner solid within the ν=1/2 fractional quantum Hall effect

Microwave spectroscopic observation of a Wigner solid within the ν=1/2 fractional quantum Hall effect

Topological kink plasmons on magnetic-domain boundaries

Observation of an Anisotropic Wigner Crystal

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