Fluorescent Ultrashort Nanotubes.

ConspectusUltrashort single-walled carbon nanotubes (SWCNTs), defined here as ∼1 to 50 nm segments, match the characteristic dimensions of biological pores, nanofluidic channels, and emerging quantum architectures, where quantum confinement, topological edge states─electronic states localized at the tube termini─and atomic defects converge to generate new functionalities for sensing, imaging, and optoelectronics. Yet this length regime has been largely inaccessible optically: ultrashort SWCNTs rarely emit light because mobile excitons rapidly diffuse to quenching sites at the tube ends. Fluorescent ultrashort nanotubes (FUNs) overcome this "dark gap" by introducing sp quantum defects, also known as organic color centers (OCCs), that localize excitons and render them radiative, enabling bright photoluminescence in the short-wave infrared, including the NIR-II bioimaging window.The FUN platform arises from three complementary advances: (1) quantum defect chemistry, which introduces molecularly tunable exciton traps; (2) super-resolution fluorescence imaging, which resolves discrete, end-localized emission sites in <40 nm nanotubes, demonstrating defect-governed radiative recombination; and (3) defect-induced chemical etching (DICE), which cuts nanotubes at preinstalled quantum defects to yield ultrashort, bright-emitting nanotube segments with intact graphitic frameworks and chemically defined termini. DICE further extends this chemical programmability by producing ultrashort nanotubes whose rim chemistry functions as molecular gates that reversibly regulate ionic transport through subnanometer pores. Beyond enabling bright ultrashort emitters and molecular gates, FUNs reveal a fundamental separation between host and defect excitons. The host SWCNT bright exciton transition () blue-shifts with decreasing length, following a Δ ∝ scaling, whereas the defect state (, historically denoted or ) remains nearly invariant with length, consistent with a deep, localized exciton trap. This length-energy decoupling provides two independent design parameters (i.e., nanotube length and localized defect chemistry) for engineering exciton energetics at ultrashort length scales.This Account traces the development of FUNs from their origins in quantum-defect chemistry to their emerging applications. We highlight how precise control over defect structure, nanotube length, and rim functionality converts previously dark ultrashort segments into a chemically precise architecture for codesigning quantum confinement, photophysics, and molecular function within a single carbon scaffold. We further discuss the opportunities and challenges ahead, pointing toward applications ranging from biomimetic channel mimics and responsive nanofluidic elements to infrared imaging probes and deterministic quantum emitters operating at the molecular limit.