The nanoscale control afforded by scanning probe microscopes has prompted the
development of a wide variety of scanning-probe-based patterning methods. Some of these …

This review describes recent groundbreaking results in Si, Si/SiGe, and dopant-based
quantum dots, and it highlights the remarkable advances in Si-based quantum physics that …

The Hubbard model is an essential tool for understanding many-body physics in condensed
matter systems. Artificial lattices of dopants in silicon are a promising method for the analog …

Human beings have witnessed unprecedented developments since the 1760s using
precision tools and manufacturing methods that have led to ever-increasing precision, from …

Electron spins confined to phosphorus donors in silicon are promising candidates as qubits
because of their long coherence times, exceeding seconds in isotopically purified bulk …

Substitutional donor atoms in silicon are promising qubits for quantum computation with
extremely long relaxation and dephasing times demonstrated. One of the critical challenges …

Quantum states of atomic systems can be directly addressed using quantum optical
microscopes. However, solid-state microscopy techniques cannot typically achieve both …

Scaling up to large arrays of donor-based spin qubits for quantum computation will require
the ability to perform high-fidelity readout of multiple individual spin qubits. Recent …

Atomically precise fabrication has an important role to play in develo** atom‐based
electronic devices for use in quantum information processing, quantum materials research …

A materials synthesis method that we call atomic-precision advanced manufacturing
(APAM), which is the only known route to tailor silicon nanoelectronics with full 3D atomic …