Litcius/Paper detail

Programming sp<sup>3</sup> Quantum Defects along Carbon Nanotubes with Halogenated DNA

Xiaojian Wu, Mijin Kim, Lucy J. Wang, Abhindev Kizhakke Veetil, YuHuang Wang

2024Journal of the American Chemical Society19 citationsDOIOpen Access PDF

Abstract

Atomic defect color centers in solid-state systems hold immense potential to advance various quantum technologies. However, the fabrication of high-quality, densely packed defects presents a significant challenge. Herein we introduce a DNA-programmable photochemical approach for creating organic color-center quantum defects on semiconducting single-walled carbon nanotubes (SWCNTs). Key to this precision defect chemistry is the strategic substitution of thymine with halogenated uracil in DNA strands that are orderly wrapped around the nanotube. Photochemical activation of the reactive uracil initiates the formation of sp 3 defects along the nanotube as deep exciton traps, with a pronounced photoluminescence shift from the nanotube band gap emission (by 191 meV for (6,5)-SWCNTs). Furthermore, by altering the DNA spacers, we achieve systematic control over the defect placements along the nanotube. This method, bridging advanced molecular chemistry with quantum materials science, marks a crucial step in crafting quantum defects for critical applications in quantum information science, imaging, and sensing.

Topics & Concepts

Carbon nanotubePhotoluminescenceChemistryNanotubeQuantum dotNanotechnologyUracilExcitonThymineBand gapDNAPhotochemistryMaterials scienceOptoelectronicsPhysicsBiochemistryQuantum mechanicsCarbon Nanotubes in CompositesGraphene research and applicationsNanopore and Nanochannel Transport Studies