%0 Journal Article %1 Laguta.2018 %A Laguta, O. %A Tuček, M. %A van Slageren, J. %A Neugebauer, P. %D 2018 %J Journal of magnetic resonance (San Diego, Calif. : 1997) %K agvsl imported %P 138--142 %R 10.1016/j.jmr.2018.09.005 %T Multi-frequency rapid-scan HFEPR %V 296 %X Gaining access to electron spin dynamics at (sub-)THz frequencies is highly challenging. However, this information is highly relevant for the understanding and development of spin polarization agents in dynamic nuclear polarization methods and single-molecule magnets for quantum computation. Here we demonstrate the first rapid-scan EPR experiment in 200 GHz frequency region. A voltage controlled oscillator (VCO) generated fast sinusoidal frequency sweeps with scan rates up to 3×105 THz/s after the frequency multiplication, which is equal to 107 T/s in field representation. Such high scan rates provide access to extremely short relaxation times T2=2π×sweeprate-0.5≈1 ns. The absence of a microwave cavity allowed us to perform multi-frequency experiments in the 170-250 GHz range. A further advantage of a cavity-less approach is the possibility to use vast sweeps, which in turn, allows the deconvolution using a linear sweep function. The deconvoluted spectra obtained with this method are identical to the slow-rate spectrum. We find spin-spin relaxation times of several nanoseconds for pure LiPc samples in this frequency range. These values cannot be obtained by means of conventional pulsed EPR methods.

@article{Laguta.2018, abstract = {Gaining access to electron spin dynamics at (sub-)THz frequencies is highly challenging. However, this information is highly relevant for the understanding and development of spin polarization agents in dynamic nuclear polarization methods and single-molecule magnets for quantum computation. Here we demonstrate the first rapid-scan EPR experiment in 200 GHz frequency region. A voltage controlled oscillator (VCO) generated fast sinusoidal frequency sweeps with scan rates up to 3×105 THz/s after the frequency multiplication, which is equal to 107 T/s in field representation. Such high scan rates provide access to extremely short relaxation times T2=2π×sweeprate-0.5≈1 ns. The absence of a microwave cavity allowed us to perform multi-frequency experiments in the 170-250 GHz range. A further advantage of a cavity-less approach is the possibility to use vast sweeps, which in turn, allows the deconvolution using a linear sweep function. The deconvoluted spectra obtained with this method are identical to the slow-rate spectrum. We find spin-spin relaxation times of several nanoseconds for pure LiPc samples in this frequency range. These values cannot be obtained by means of conventional pulsed EPR methods.}, added-at = {2018-10-26T17:40:08.000+0200}, author = {Laguta, O. and Tuček, M. and {van Slageren}, J. and Neugebauer, P.}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2ef122ac3b6871d405581a6e0fe6211da/mariowinkler}, doi = {10.1016/j.jmr.2018.09.005}, interhash = {943b6efbe93ad16f648a9aed316c88d1}, intrahash = {ef122ac3b6871d405581a6e0fe6211da}, journal = {Journal of magnetic resonance (San Diego, Calif. : 1997)}, keywords = {agvsl imported}, pages = {138--142}, timestamp = {2018-10-26T15:50:00.000+0200}, title = {Multi-frequency rapid-scan HFEPR}, volume = 296, year = 2018 }