RESUMO
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 significantly increases T1, likely due to a less lossy native surface oxide. However, understanding the formation mechanism and nature of both surface oxides is still limited. Using aberration-corrected transmission electron microscopy and electron energy loss spectroscopy, we found that Ta surface oxide has fewer suboxides than Nb oxide. We observed an abrupt oxidation state transition from Ta2O5 to Ta, as opposed to the gradual shift from Nb2O5, NbO2, and NbO to Nb, consistent with thermodynamic modeling. Additionally, amorphous Ta2O5 exhibits a closer-to-crystalline bonding nature than Nb2O5, potentially hindering H atomic diffusion toward the oxide/metal interface. Finally, we propose a loss mechanism arising from the transition between two states within the distorted octahedron in an amorphous structure, potentially causing two-level system loss. Our findings offer a deeper understanding of the differences between native amorphous Ta and Nb oxides, providing valuable insights for advancing superconducting qubits through surface oxide engineering.
RESUMO
S-nitrosothiols (SNOs) are small naturally occurring thiol and nitric oxide adducts that participate in many cell signaling pathways in living organisms. SNOs receive widespread attention in cell biology, biochemistry and chemistry because they can donate nitric oxide and/or nitrosonium ions in S-nitrosylation reactions, which are comparable to phosphorylation, acetylation, glutathionylation, and palmitoylation reactions. SNOs have advantageous effects in respiratory diseases and other systems in the body. S-nitrosylation signaling is a metabolically regulated physiological process that leads to specific post-translational protein modifications. S-nitrosylation signaling is faulty in cystic fibrosis (CF) and many other lung diseases. CF is an inherited, lethal autosomal recessive multisystem disease resulting from mutations in the gene encoding the CF transmembrane conductance regulatory (CFTR) protein. F508del CFTR is the most common mutation associated with CF, which results in CFTR misfolding because a phenylalanine is deleted from the primary structure of CFTR. The majority of wild-type CFTR and almost all F508del is degraded before reaching the cell surface. Ultimately, CF researchers have been looking to correct the mutated CFTR protein in the CF patients. Remarkably, researchers have found that SNOs levels are low in the CF lower airway compared to non-CF patients. We have been interested in determining whether SNOs increase CFTR maturation through S-nitrosylation. Maturation of both wild type and mutant F508del CFTR increases SNOs, which up-regulate CFTR maturation. In this review, we summarized our current knowledge of S-nitrosothiols signaling in cystic fibrosis airways.