Fagan, J.
, Castellano, R.
, Yang, D.
, Park, S.
, Shapturenka, P.
, Praino, R.
, Fornasiero, F.
and Shan, J.
(2025),
Efficient measurement of length distribution of 1D nanoparticles in solution via optical polarimetry, ACS Nano, [online], https://doi.org/10.1021/acsnano.5c14994, https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=960545
(Accessed April 9, 2026)
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Efficient measurement of length distribution of 1D nanoparticles in solution via optical polarimetry
Published
Author(s)
, Richard Castellano, Da-Chi Yang, Sei Jin Park, Pavel Shapturenka, Robert Praino, Francesco Fornasiero, Jerry Shan
Abstract
The efficient measurement of the length distribution of nanotubes, nanowires, and other 1D nanoparticles in solution is important to enable their incorporation into materials and devices, and to optimize their processing for properties of interest, such as thermal/electrical conductivity or mechanical strength, in suspensions and composites. We report an electric-field- (E-field-) assisted optical-polarimetry technique to measure the length distribution of ensembles of high-aspect-ratio particles in dilute suspension. The degree of alignment of polarizable 1D particles suspended in a fluid under Brownian motion explicitly depends on the E-field strength and the particle length. We show that it is possible to extract the length distribution of 1D nanoparticles suspended in an insulating fluid by applying a range of E-fields and using optical polarimetry to measure the corresponding alignment-order parameter. Notably, the method is relatively insensitive to the diameter of the 1D particles, which can be poorly known or vary within a sample. The technique is validated with silver nanowires and carbon nanotubes of known lengths, as well as polymer-depletion-length-separated (PDLS) single-wall-carbon-nanotube (SWCNT) samples with length distributions independently measured with analytical ultracentrifugation. Finally, we demonstrate the ability of the optical-polarimetry technique to quantify changes in length distribution of ultra-narrow, sub-nanometer-diameter SWCNT samples under different types and durations of ultrasonication. Within its range of applicability (polarizable 1D nanoparticles in the 0.5 – 15 μm length range), the E-field-assisted optical-polarimetry method is a particularly efficient and accurate method to measure the length distribution of nanowires and nanotubes in suspension.Citation
ACS Nano
Volume
19
Pub Type
Journals
Download Paper
Keywords
nanotube, 1D, length, polarimetry
Citation
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Created December 1, 2025, Updated April 8, 2026