A Review of Scientific Instruments

TL;DR: The experimentally realized coherent control of a single-electron spin in a quantum dot using an oscillating electric field generated by a local gate to establish the feasibility of fully electrical manipulation of spin qubits.

TL;DR: An improvement of more than two orders of magnitude is demonstrated in the spin coherence time of nitrogen-vacancy centres of diamond, which could advance quantum sensing, enable squeezing and many-body entanglement, and open a path to simulating driven, interaction-dominated quantum many- body Hamiltonians.

TL;DR: The coupling of electron-spin ensembles to a superconducting transmission-line cavity at strengths greatly exceeding the cavity decay rates and comparable to the spin linewidths is demonstrated.

TL;DR: In addition to the operational limits imposed by MHD stability on plasma current and pressure, an independent limit on plasma density is observed in confined toroidal plasmas as mentioned in this paper, where all toroidal confinement devices considered operate in similar ranges of (suitably normalized) densities.

TL;DR: This article presents a deflection measurement setup for Atomic Force Microscopy (AFM), based on a quadrature phase differential interferometer, which presents an excellent long-term stability and a constant sensitivity independent of the optical phase of the interferometers.

TL;DR: Analytical and empirical evidence is given that characterizes false convergence on stochastic functions, and several modifications are discussed to reduce the likelihood of false convergence.

TL;DR: An acoustics-based method for the rapid arrangement of microscopic particles into organized and programmable architectures, which are periodically spaced within a square assembly chamber, which offers several notable advantages over other approaches including simplicity, speed and scalability.

TL;DR: In this article, the velocity sensitivity model of a single laser beam incident in an arbitrary direction on a rotating target undergoing arbitrary vibration is presented as the sum of six terms, each the product of a combination of geometric parameters, relating to the laser beam orientation, and the combination of motion parameters.