Abstract
Ultrapure semiconducting single-walled carbon nanotube (sc-SWNT) dispersions produced through conjugated polymer sorting are ideal candidates for the fabrication of solution-processed organic electronic devices on a commercial scale. Protocols for sorting and dispersing ultrapure sc-SWNTs with conjugated polymers for thin-film transistor (TFT) applications have been well refined. Conventional wisdom dictates that removal of excess unbound polymer through filtration or centrifugation is necessary to produce high-performance TFTs. However, this is time-consuming, wasteful, and resource-intensive. In this report, we challenge this paradigm and demonstrate that excess unbound polymer during semiconductor film fabrication is not necessarily detrimental to device performance. Over 1200 TFT devices were fabricated from 30 unique polymer-sorted SWNT dispersions, prepared using two different alternating copolymers. Detailed Raman spectroscopy, x-ray photoelectron spectroscopy (XPS), and atomic force microscopy (AFM) studies of the random-network semiconductor films demonstrated that a simple solvent rinse during TFT fabrication was sufficient to remove unbound polymer from the sc-SWNT films, thus eliminating laborious polymer removal before TFT fabrication. Furthermore, below a threshold polymer concentration, the presence of excess polymer during fabrication did not significantly impede TFT performance. Preeminent performance was achieved for devices prepared from native polymer-sorted SWNT dispersions containing the "original" amount of excess unbound polymer (immediately following enrichment). Lastly, we developed an open-source Machine Learning algorithm to quantitatively analyze AFM images of SWNT films for surface coverage, number of tubes, and tube alignment.
Highlights
Semiconducting single-walled carbon nanotubes are prospective nanomaterials for flexible, inexpensive, and solution-processable electronics
Our results show that devices prepared from as-produced polymersorted SWNT dispersions perform no worse than thin-film transistor (TFT) prepared after removal of unbound polymer, challenging the notion that excess polymer removal is necessary for fabricating high-performing SWNT TFTs
We demonstrate that TFTs fabricated from polymer-sorted SWNT dispersions containing residual excess polymer perform identical to or even better than dispersions where the excess polymer is removed prior to device formation
Summary
Semiconducting single-walled carbon nanotubes (sc-SWNTs) are prospective nanomaterials for flexible, inexpensive, and solution-processable electronics. If chosen properly, can consistently yield sc-SWNT dispersions with purities in excess of 99.9%.6. These supramolecular polymer−SWNT complexes have been successfully incorporated into thin-film transistors (TFTs),[7−9] organic photovoltaic devices (OPVs),[10,11] and integrated circuits.[6,12−15] Throughout the past decade, researchers have made impressive gains in TFTs with semiconducting layers composed of polymer-sorted scSWNTs, with devices consistently outperforming organic small-molecule and polymer semiconductors; polymer-sorted. Each step from SWNT sorting and dispersion to TFT fabrication requires optimization for both device performance and commercial scalability
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