Isotopic enrichment of silicon by high fluence 28Si- ion implantation

Abstract

Spins in the `semiconductor vacuum' of silicon-28 (28Si) are suitable qubit candidates due to their long coherence times. An isotopically purified substrate of 28Si is required to limit the decoherence pathway caused by magnetic perturbations from surrounding 29Si nuclear spins (I=1/2), present in natural Si (nat Si) at an abundance of 4.67%. We isotopically enrich surface layers of nat Si by sputtering using high fluence 28Si- implantation. Phosphorus (P) donors implanted into one such 28Si layer with ~3000 ppm 29Si, produced by implanting 30 keV 28Si- ions at a fluence of 4x1018 cm-2, were measured with pulsed electron spin resonance, confirming successful donor activation upon annealing. The mono-exponential decay of the Hahn echo signal indicates a depletion of 29Si. A coherence time of T2 = 285 +/- 14 us is extracted, which is longer than that obtained in nat Si for similar doping concentrations and can be increased by reducing the P concentration in future. The isotopic enrichment was improved by employing one-for-one ion sputtering using 45 keV 28Si- implantation. A fluence of 2.63x1018 cm-2 28Si- ions were implanted at this energy into nat Si, resulting in an isotopically enriched surface layer ~100 nm thick; suitable for providing a sufficient volume of 28Si for donor qubits implanted into the near-surface region. We observe a depletion of 29Si to 250 ppm as measured by secondary ion mass spectrometry. The impurity content and the crystallization kinetics via solid phase epitaxy are discussed. The 28Si layer is confirmed to be a single crystal using transmission electron microscopy. This method of Si isotopic enrichment shows promise for incorporating into the fabrication process flow of Si spin qubit devices.