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Related Concept Videos

Atomic Nuclei: Nuclear Magnetic Moment00:59

Atomic Nuclei: Nuclear Magnetic Moment

All atomic nuclei are positively charged. When they have a nonzero spin, they behave like rotating charges. As a consequence of their charge and spin, these nuclei generate a magnetic field (B). This, in turn, gives rise to a magnetic moment (μ), which is randomly oriented in the absence of an external magnetic field. When an external magnetic field (B0) is applied, the magnetic moment vectors can align with the field or against it in 2 + 1 orientations. A hydrogen nucleus, which is just a...
Chirality02:25

Chirality

Chirality is a term that describes the lack of mirror symmetry in an object. In other words, chiral objects cannot be superposed on their mirror images. For example, our feet are chiral, as the mirror image of the left foot, the right foot, cannot be superposed on the left foot.
Chiral objects exhibit a sense of handedness when they interact with another chiral object. For example, our left foot can only fit in the left shoe and not in the right shoe. Achiral objects — objects that have...
Atomic Nuclei: Magnetic Resonance01:05

Atomic Nuclei: Magnetic Resonance

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...
Chirality at Nitrogen, Phosphorus, and Sulfur02:30

Chirality at Nitrogen, Phosphorus, and Sulfur

Chirality is most prevalent in carbon-based tetrahedral compounds, but this important facet of molecular symmetry extends to sp3-hybridized nitrogen, phosphorus and sulfur centers, including trivalent molecules with lone pairs. Here, the lone pair behaves as a functional group in addition to the other three substituents to form an analogous tetrahedral center that can be chiral.
A consequence of chirality is the need for enantiomeric resolution. While this is theoretically possible for all...
Chirality in Nature02:30

Chirality in Nature

Chirality is the most intriguing yet essential facet of nature, governing life’s biochemical processes and precision. It can be observed from a snail shell pattern in a macroscopic world to an amino acid, the minutest building block of life. Most of the snails around the world have right-coiled shells because of the intrinsic chirality in their genes. All the amino acids present in the human body exist in an enantiomerically pure state, except for glycine - the sole achiral amino acid. The...
Magnetic Moment of an Electron01:23

Magnetic Moment of an Electron

Electrons revolving around a nucleus are analogous to a circular current carrying loop. This current produces a magnetic dipole moment proportional to the electron's orbital angular momentum. Since the orbital angular momentum is quantized in terms of the reduced Planck's constant, the dipole moment is quantized in the Bohr Magneton. The value of the Bohr magneton is 9.27 x 10-24 Am2. Electrons also have an intrinsic spin angular momentum, and the associated spin magnetic moment is...

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Elliptic flow at large transverse momenta from quark coalescence.

Physical review letters·2003
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Related Experiment Video

Updated: Jun 5, 2026

Comparison of Two Different Synthesis Methods of Single Crystals of Superconducting Uranium Ditelluride
04:51

Comparison of Two Different Synthesis Methods of Single Crystals of Superconducting Uranium Ditelluride

Published on: July 8, 2021

Testing the chiral magnetic effect with central U+U collisions.

Sergei A Voloshin1

  • 1Wayne State University, Detroit, Michigan 48201, USA.

Physical Review Letters
|January 15, 2011
PubMed
Summary

Investigating the chiral magnetic effect (CME) in nuclear collisions requires disentangling its charge separation signals from background correlations. Proposed experiments using central U+U collisions and isobaric beams aim to clarify CME contributions.

Area of Science:

  • Nuclear Physics
  • High-Energy Physics
  • Quantum Chromodynamics

Background:

  • Quark interactions with gluonic fields violate parity (P) and charge-parity (CP) symmetries.
  • Strong magnetic fields in noncentral nuclear collisions can induce charge separation via the chiral magnetic effect (CME).
  • Recent experimental data show correlations consistent with CME but are potentially confounded by background effects.

Purpose of the Study:

  • To propose methods for definitively identifying the chiral magnetic effect (CME) in nuclear collisions.
  • To differentiate CME-induced charge separation from background correlations like elliptic flow.
  • To enable more quantitative studies of CME through specific experimental designs.

Main Methods:

  • Utilizing central body-body Uranium-Uranium (U+U) collisions.

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Coulomb Explosion Imaging as a Tool to Distinguish Between Stereoisomers
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Coulomb Explosion Imaging as a Tool to Distinguish Between Stereoisomers

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Related Experiment Videos

Last Updated: Jun 5, 2026

Comparison of Two Different Synthesis Methods of Single Crystals of Superconducting Uranium Ditelluride
04:51

Comparison of Two Different Synthesis Methods of Single Crystals of Superconducting Uranium Ditelluride

Published on: July 8, 2021

Preparing an Isotopically Pure 229Th Ion Beam for Studies of 229mTh
10:42

Preparing an Isotopically Pure 229Th Ion Beam for Studies of 229mTh

Published on: May 3, 2019

Coulomb Explosion Imaging as a Tool to Distinguish Between Stereoisomers
08:51

Coulomb Explosion Imaging as a Tool to Distinguish Between Stereoisomers

Published on: August 18, 2017

  • Analyzing charge-dependent correlations.
  • Comparing results with theoretical predictions for CME and background effects.
  • Proposing future studies with collisions of isobaric beams.
  • Main Results:

    • Current experimental results are suggestive of CME but lack definitive confirmation due to potential background contributions.
    • The proposed experimental approach aims to isolate the CME signal.
    • Isobaric beam collisions offer potential for more precise quantitative analysis.

    Conclusions:

    • Disentangling CME from background correlations is crucial for understanding fundamental symmetries in nuclear matter.
    • Central U+U collisions and isobaric beam studies are proposed as key experimental strategies.
    • Further quantitative studies are needed to confirm the CME signal and its properties.