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The dynamics of hole-conjugated fractional quantum Hall states is poorly understood due to the limitations of current experimental probes. Here the authors study the high-frequency dynamics of edge modes at filling factor 2/3, precisely identifying the tunneling charge and damping of constituent charge modes.

Quantum tomography of individual electrons, which in principle yields complete knowledge of their quantum states, is demonstrated by initially preparing them in a well-controlled quantum state called a leviton.

Thermoelectric devices convert waste heat to electrical power but suffer from low efficiency. Roche et al.create a mesoscopic heat engine comprising capacitively coupled hot and cold electrical circuits in which thermal fluctuations in the former are converted to potential fluctuations in the latter

The detection of high-frequency radiation emitted by a quantum conductor is promising but current approaches exhibit limited sensitivity. Here, Jompol et al. propose on-chip radiation detection based on photo-assisted shot noise and show the response to be independent of the nature and geometry of the quantum conductor.

Dirac fermions at ap–njunction can exhibit a wide variety of unusual properties. Here, the authors investigate the dynamics of such fermions in a graphene junction using shot noise measurements and demonstrate the crucial role of junction length.

Excitations of the fractional quantum Hall states are of great interest because they obey anyonic statistics, but electronic interferometers give contrasting results about their quantum coherence. Here the authors use novel two-particle time-domain interferometry to show that quantum coherence is indeed preserved.

Propagating spin waves known as magnons are expected to carry a dipole moment in the quantum Hall regime. Now, this moment has been detected, demonstrating that the degrees of freedom of spin and charge are entangled in quantum Hall magnons.

Minimal-excitation fermionic quasiparticles are created by applying a potential with Lorentzian time dependence to the contact of a narrow constriction in a two-dimensional electron gas.

Sensitive measurements of fluctuations in the current through carbon-nanotube-based quantum dots provide insight into the many-body physics of such systems.

Quantum Hall edge channels provide a platform to study electron interference, however understanding decoherence in these systems remains an open problem. Jo et al. realize a regime of suppressed decoherence in an electronic Mach-Zehnder interferometer formed in a graphene quantum Hall pn junction.

Realizing the ampere, the unit of electrical current, involves controlling a flow of elementary charges with high accuracy. Here, the authors present the generation of sizeable currents at quantized values with relative uncertainties below 10⁻⁸.

Large-area graphene devices synthesized by chemical vapour deposition are used to develop electrical resistance standards, based on the quantum Hall effect, with state-of-the-art accuracy and under an extended range of experimental conditions of magnetic field, temperature and current.

The Coulomb force between charges has a much greater influence on the electronic characteristics of 1D conductors than it does in 3D. Bocquillon et al. identify the separation of neutral and charged 1D edge modes, driven by Coulomb interactions in a quantum Hall system.

Gapless edge-state excitations known as one-dimensional chiral fermions explain many experimental observations of the behaviour of integer quantum Hall systems. But prevailing theory suggests the emergence of extra edge states as well. A new spectroscopic technique for probing the flow of energy in the edge channels of a quantum Hall device finds no loss of energy to such extra states.

A record force sensitivity at low temperatures is now reported using a carbon nanotube mechanical resonator.