T1- and T2-spin relaxation time limitations of phosphorous donor electrons near crystalline silicon to silicon dioxide interface defects

Abstract

A study of donor electron spins and spin--dependent electronic transitions involving phosphorous (31P) atoms in proximity of the (111) oriented crystalline silicon (c-Si) to silicon dioxide (SiO2) interface is presented for [31P] = 1015 cm-3 and [31P] = 1016 cm-3 at about liquid 4He temperatures (T = 5 K - 15 K). Using pulsed electrically detected magnetic resonance (pEDMR), spin--dependent transitions between the donor state and two distinguishable interface states are observed, namely (i) centers which can be identified by their characteristic anisotropy and (ii) a more isotropic center which is attributed to E defects of the bulk close to the interface. Correlation measurements of the dynamics of spin--dependent recombination confirm that previously proposed transitions between and the interface defects take place. The influence of these electronic near--interface transitions on the donor spin coherence time T2 as well as the donor spin--lattice relaxation time T1 is then investigated by comparison of spin Hahn--echo decay measurements obtained from conventional bulk sensitive pulsed electron paramagnetic resonance and surface sensitive pEDMR, as well as surface sensitive electrically detected inversion recovery experiments. The measurements reveal that both T2 and T1 of donor electrons spins in proximity of energetically lower interface states at T≤ 13 K are reduced by several orders of magnitude.