Electron Spin Relaxation and 39K Pulsed ENDOR Studies on Cr5+ doped K3NbO8 at 9.7 and 240 GHz

Abstract

Cr5+ doped K3NbO8, considered to be useful as a electron spin qubit, has been investigated by pulsed X-band (~9.7 GHz) and 240 GHz electron paramagnetic resonance and electron nuclear double resonance (ENDOR). Comparison of the low temperature electronic spin-lattice relaxation rate 1/T1 at 9.7 and 240 GHz shows that it is 250 times faster at 240 GHz than at X-band. On the other hand, the spin-spin relaxation rate 1/T2 appears largely frequency independent and is very likely related to the superhyperfine (SHF) coupling of the Cr5+ electron with the surrounding potassium and niobium nuclei. This coupling was investigated by HYSCORE at 9.7 GHz and pulsed Mims ENDOR at 240 GHz. The high frequency and field enabled us to unambiguously measure the hyperfine and quadrupole couplings of the 39K in spite of its small magnetic moment. We find that the largest 39K SHF coupling is positive, with 0.522 MHz and 0.20 MHz as its isotropic and dipolar parts respectively. 93Nb ENDOR was dominantly due to its quadrapolar interaction, with a coupling of about 0.8 MHz, and a SHF coupling of about 0.08 MHz. The significance of these data to spin qubit studies is pointed out.