A new class of correlated quasiparticle states discovered in a multi-valley semiconductor using optical absorption measurements in pulsed magnetic fields. This new type of multi-particle state results when excitons interact simultaneously with multiple electron reservoirs that are quantum-mechanically distinguishable by virtue of having different spin and/or valley quantum numbers.

High-magnetic-field, high-frequency electron paramagnetic resonance demonstrates how coordination chemistry can be leveraged to stabilize a desired electronic/magnetic state in an organic molecule. In this experiment, the long-sought magnetic (triplet) ground state in a benzene ring is stabilized by a pair of metal ions above and below the six-carbon ring.

Learn how the MagLab's high-field magnets are helping uncover the secrets of "forever chemicals."

Researchers reveal how carbohydrates form plant biomass, information that may lead to new biorenewable energy solutions. 

New research explores the power of intersecting identities in a young Black woman’s STEM experience.

Theory predicted that the transition between the superconducting and superfluid regimes should be continuous for electrons and holes in solid materials, but recent high magnetic field experiments performed by researchers from Columbia, Harvard and Brown Universities demonstrated the crossover between coupling regimes.

A new Blood Proteoform Atlas maps 30,000 unique proteoforms as they appear in 21 different cell types found in human blood. The MagLab's 21 tesla FT-ICR mass spectrometer contributed nearly a third of the atlas' proteoforms. 

MagLab users have discovered that magnetism is key to understanding the behavior of electrons in high-temperature superconductors.