Quantum computing stands at the precipice of technological revolution, promising
unprecedented computational capabilities to tackle some of humanity's most complex …

The performance of superconducting quantum circuits for quantum computing has advanced
tremendously in recent decades; however, a comprehensive understanding of relaxation …

Improving the qubit's lifetime (T1) is crucial for fault-tolerant quantum computing. Recent
advancements have shown that replacing niobium (Nb) with tantalum (Ta) as the base metal …

Andreev (or superconducting) spin qubits (ASQs) have recently emerged as a promising
qubit platform that combines superconducting circuits with semiconductor spin degrees of …

Qubit-specific measurement in a superconducting quantum processor requires physical
interconnects that traverse 4 orders of magnitude in temperature from 293 K to 10 mK …

The development of superconducting qubit technology has shown great potential for the
construction of practical quantum computers,. As the complexity of quantum processors …

Superconducting quantum circuits (SQC) are one of the most promising hardware platforms
for quantum computing, yet their performance is currently limited by the presence of various …

In planar superconducting circuits, decoherence due to materials imperfections, especially
two-level-system (TLS) defects at different interfaces, is a primary hurdle for advancing …

An ultra-thin aluminum oxide layer is a key component for Josephson junctions (JJ) in
superconducting quantum bits (qubits). This layer serves as a barrier layer for Cooper pairs …

The current performance of superconducting circuit-based quantum processors is limited by
the poor understanding of interface physics, including native surface oxide formation on the …