Selective extraction of semiconducting carbon nanotubes is a key step in the production of high-performance, solution-processed electronics. Here, we describe the ability of a supramolecular sorting polymer to selectively disperse semiconducting carbon nanotubes from five commercial sources with diameters ranging from 0.7 to 2.2 nm. The sorting purity of the largest-diameter nanotubes (1.4 to 2.2 nm; from Tuball) was confirmed by short channel measurements to be 97.5%. Removing the sorting polymer by acid-induced disassembly increased the transistor mobility by 94 and 24% for medium-diameter and large-diameter carbon nanotubes, respectively. Among the tested single-walled nanotube sources, the highest transistor performance of 61 cm/V·s and on/off ratio >10 were realized with arc discharge carbon nanotubes with a diameter range from 1.2 to 1.7 nm. The length and quality of nanotubes sorted from different sources is compared using measurements from atomic force microscopy and Raman spectroscopy. The transistor mobility is found to correlate with the G/D ratio extracted from the Raman spectra.
Particle
size is a key parameter that must be measured to ensure reproducible
production of cellulose nanocrystals (CNCs) and to achieve reliable
performance metrics for specific CNC applications. Nevertheless, size
measurements for CNCs are challenging due to their broad size distribution,
irregular rod-shaped particles, and propensity to aggregate and agglomerate.
We report an interlaboratory comparison (ILC) that tests transmission
electron microscopy (TEM) protocols for image acquisition and analysis.
Samples of CNCs were prepared on TEM grids in a single laboratory,
and detailed data acquisition and analysis protocols were provided
to participants. CNCs were imaged and the size of individual particles
was analyzed in 10 participating laboratories that represent a cross
section of academic, industrial, and government laboratories with
varying levels of experience with imaging CNCs. The data for each
laboratory were fit to a skew normal distribution that accommodates
the variability in central location and distribution width and asymmetries
for the various datasets. Consensus values were obtained by modeling
the variation between laboratories using a skew normal distribution.
This approach gave consensus distributions with values for mean, standard
deviation, and shape factor of 95.8, 38.2, and 6.3 nm for length and
7.7, 2.2, and 2.9 nm for width, respectively. Comparison of the degree
of overlap between distributions for individual laboratories indicates
that differences in imaging resolution contribute to the variation
in measured widths. We conclude that the selection of individual CNCs
for analysis and the variability in CNC agglomeration and staining
are the main factors that lead to variations in measured length and
width between laboratories.
We present the conducting polymer poly (3,4-ethylenedioxythiophene) (PEDOT) doped with an algal-derived glycan extract, Phycotrix™ [xylorhamno-uronic glycan (XRU84)], as an innovative electrically conductive material capable of providing beneficial biological and electrical cues for the promotion of favorable wound healing processes. Increased loading of the algal XRU84 into PEDOT resulted in a reduced surface nanoroughness and interfacial surface area and an increased static water contact angle. PEDOT-XRU84 films demonstrated good electrical stability and charge storage capacity and a reduced impedance relative to the control gold electrode. A quartz crystal microbalance with dissipation monitoring study of protein adsorption (transferrin, fibrinogen, and collagen) showed that collagen adsorption increased significantly with increased XRU84 loading, while transferrin adsorption was significantly reduced. The viscoelastic properties of adsorbed protein, characterized using the ΔD/Δf ratio, showed that for transferrin and fibrinogen, a rigid, dehydrated layer was formed at low XRU84 loadings. Cell studies using human dermal fibroblasts demonstrated excellent cell viability, with fluorescent staining of the cell cytoskeleton illustrating all polymers to present excellent cell adhesion and spreading after 24 h.
Vat photopolymerization (VP) is an advanced additive manufacturing (AM) platform that enables production of intricate 3D monoliths that are unattainable with conventional manufacturing methods. In this work, modification of amorphous poly(arylene ether sulfone)s (PSU) allows for VP printing. Post-polymerization telechelic functionalization with acrylate functionality yielded photocrosslinkable PSUs across a molecular weight range. 1 H NMR spectroscopy confirms chemical composition and quantitative acrylate functionalization. Addition of diphenyl-(2,4,6-trimethylbenzoyl)phosphine oxide (TPO) photoinitiator to 30 wt% PSU solutions in NMP provides a photocurable composition. However, subsequent photorheological studies elucidate rapid photodegradation of the polysulfone main chain, which is especially apparent in high M n (15 kg mol −1 ) PSU formulations. UV-light intensity and wavelength range are altered to reduce degradation while allowing for efficient crosslinking. The addition of 0.5 wt% of avobenzone photoblocker produces an ill-defined structure with 6 kg mol −1 PSU. For higher molecular weights (>12 kg mol −1 ), solutions with a low molar mass reactive diluent, i.e., trimethylolpropane triacrylate, enable the printing of an organogel with a storage modulus (>10 5 Pa) sufficient for vat photopolymerization. Employing multicomponent solutions provide well-defined parts with complex geometries through vat photopolymerization.
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