Litcius/Paper detail

Gadolinium Spin Decoherence Mechanisms at High Magnetic Fields

C. Blake Wilson, Mian Qi, Songi Han, Mark S. Sherwin

2023The Journal of Physical Chemistry Letters10 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Favorable relaxation processes, high-field spectral properties, and biological compatibility have made spin-7/2 Gd 3+ -based spin labels an increasingly popular choice for protein structure studies using high-field electron paramagnetic resonance. However, high-field relaxation and decoherence in ensembles of half-integer high-spin systems, such as Gd 3+, remain poorly understood. We report spin–lattice ( T 1 ) and phase memory ( T M ) relaxation times at 8.6 T (240 GHz), and we present the first comprehensive model of high-field, high-spin decoherence accounting for both the electron spin concentration and temperature. The model includes four principal mechanisms driving decoherence: energy-conserving electron spin flip-flops, direct “ T 1 ” spin–lattice relaxation-driven electron spin flip processes, indirect T 1 -driven flips of nearby electron spins, and nuclear spin flip-flops. Mechanistic insight into decoherence can inform the design of experiments making use of Gd 3+ as spin probes or relaxivity agents and can be used to measure local average interspin distances as long as 17 nm.

Topics & Concepts

Quantum decoherenceSpin engineeringPhysicsCondensed matter physicsPulsed EPRSpin (aerodynamics)Electron paramagnetic resonanceSpin polarizationElectronSpin echoQuantum mechanicsQuantumThermodynamicsMedicineMagnetic resonance imagingRadiologyElectron Spin Resonance StudiesAdvanced NMR Techniques and ApplicationsLanthanide and Transition Metal Complexes