Tunneling probe-based identification of the sp3 dangling bond on the H-C(100):2×1 surface

Abstract

The sp3 dangling bond on the diamond surface plays a critical role in the performance and fabrication of diamond quantum technologies. For the former, the magnetic and electric properties of this defect can impede the performance of quantum sensors and computers. For the latter, the chemical properties of the dangling bond are integral to proposed methods for bottom-up fabrication of scalable diamond quantum devices. In pursuit of high performance and scalable diamond quantum technology, tunneling probe-based techniques offers the ability to create and modify the sp3 dangling bond with atomic-scale precision. However, these capabilities cannot be realised either deterministically or at scale without a means for identifying the sp3 dangling bond amidst the myriad of other defects on the diamond surface. Consequently, in this work we provide a comprehensive experimental and theoretical framework for STS-based characterisation of the sp3 defect on the H-terminated (100) diamond surface. This capability provides the foundation for future tunneling probe studies in the modification of dangling bonds.