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Atomic Nuclei: Magnetic Resonance01:05

Atomic Nuclei: Magnetic Resonance

958
The number of nuclear spins aligned in the lower energy state is slightly greater than those in the higher energy state. In the presence of an external magnetic field, as the spins precess at the Larmor frequency, the excess population results in a net magnetization oriented along the z axis. When a pulse or a short burst of radio waves at the Larmor frequency is applied along the x axis, the coupling of frequencies causes resonance and flips the nuclear spins of the excess population from the...
958
Atomic Nuclei: Nuclear Spin State Overview01:03

Atomic Nuclei: Nuclear Spin State Overview

1.5K
NMR-active nuclei have energy levels called 'spin states' that are associated with the orientations of their nuclear magnetic moments. In the absence of a magnetic field, the nuclear magnetic moments are randomly oriented, and the spin states are degenerate. When an external magnetic field is applied, the spin states have only 2 + 1 orientations available to them. A proton with = ½ has two available orientations. Similarly, for a quadrupolar nucleus with a nuclear spin value of one, the...
1.5K
Atomic Nuclei: Nuclear Relaxation Processes01:23

Atomic Nuclei: Nuclear Relaxation Processes

908
In the absence of an external magnetic field, nuclear spin states are degenerate and randomly oriented. When a magnetic field is applied, the spins begin to precess and orient themselves along (lower energy) or against (higher energy) the direction of the field. At equilibrium, a slight excess population of spins exists in the lower energy state. Because the direction of the magnetic field is fixed as the z-axis,  the precessing magnetic moments are randomly oriented around the z-axis.
908
Atomic Nuclei: Nuclear Spin State Population Distribution01:14

Atomic Nuclei: Nuclear Spin State Population Distribution

1.5K
Near absolute zero temperatures, in the presence of a magnetic field, the majority of nuclei prefer the lower energy spin-up state to the higher energy spin-down state. As temperatures increase, the energy from thermal collisions distributes the spins more equally between the two states. The Boltzmann distribution equation gives the ratio of the number of spins predicted in the spin −½ (N−) and spin +½ (N+) states.
1.5K
NMR Spectroscopy: Spin–Spin Coupling01:08

NMR Spectroscopy: Spin–Spin Coupling

2.6K
The spin state of an NMR-active nucleus can have a slight effect on its immediate electronic environment. This effect propagates through the intervening bonds and affects the electronic environments of NMR-active nuclei up to three bonds away; occasionally, even farther. This phenomenon is called spin–spin coupling or J-coupling. Coupling interactions are mutual and result in small changes in the absorption frequencies of both nuclei involved. While nuclei of the same element are involved...
2.6K
Valence Bond Theory02:42

Valence Bond Theory

10.1K
Coordination compounds and complexes exhibit different colors, geometries, and magnetic behavior, depending on the metal atom/ion and ligands from which they are composed. In an attempt to explain the bonding and structure of coordination complexes, Linus Pauling proposed the valence bond theory, or VBT, using the concepts of hybridization and the overlapping of the atomic orbitals. According to VBT, the central metal atom or ion (Lewis acid) hybridizes to provide empty orbitals of suitable...
10.1K

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Related Experiment Video

Updated: Nov 15, 2025

Recombination Dynamics in Thin-film Photovoltaic Materials via Time-resolved Microwave Conductivity
11:30

Recombination Dynamics in Thin-film Photovoltaic Materials via Time-resolved Microwave Conductivity

Published on: March 6, 2017

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Cavity-enhanced microwave readout of a solid-state spin sensor.

Erik R Eisenach1,2, John F Barry3, Michael F O'Keeffe2

  • 1Massachusetts Institute of Technology, Cambridge, MA, USA.

Nature Communications
|March 2, 2021
PubMed
Summary

Researchers developed a high-fidelity readout technique for solid-state spin sensors using microwave cavities. This method overcomes limitations of optical readout, improving quantum sensing and information applications.

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Optimizing Magnetic Force Microscopy Resolution and Sensitivity to Visualize Nanoscale Magnetic Domains
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Area of Science:

  • Quantum physics
  • Materials science
  • Nanotechnology

Background:

  • Solid-state spin defects are crucial for quantum technologies but suffer from poor readout fidelity.
  • Existing readout techniques, often optical, have limitations like photon shot noise.
  • A universal, high-fidelity readout method is needed for widespread adoption of spin-based devices.

Purpose of the Study:

  • To demonstrate a high-fidelity, room-temperature readout technique for solid-state spin ensembles.
  • To overcome the limitations of conventional fluorescence-based readout methods.
  • To enhance the performance of quantum sensors based on spin defects.

Main Methods:

  • Utilized strong coupling between an ensemble of nitrogen-vacancy centers and a dielectric microwave cavity.
  • Applied techniques from cryogenic circuit cavity quantum electrodynamics for room-temperature operation.
  • Probed the spin ensemble's microwave transition directly via collective interaction.

Main Results:

  • Achieved high-fidelity, room-temperature readout of nitrogen-vacancy centers.
  • Overcame optical photon shot noise limitations inherent in fluorescence readout.
  • Demonstrated magnetic sensitivity in magnetometry approaching the Johnson-Nyquist noise limit.

Conclusions:

  • The demonstrated microwave cavity readout offers a universal and high-fidelity solution for solid-state spin sensors.
  • This technique significantly advances quantum sensing, quantum information, and fundamental physics research.
  • Future improvements in ensemble size, linewidth, or cavity quality factor can lead to unity readout fidelity.