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Bibliographic Details
Main Authors: Nguyen, M. D., Simon, J. S., Scott, J. W., Tsai, Y. C. Cincia, Zimmerman, A. M., Halperin, W. P.
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2301.11261
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author Nguyen, M. D.
Simon, J. S.
Scott, J. W.
Tsai, Y. C. Cincia
Zimmerman, A. M.
Halperin, W. P.
author_facet Nguyen, M. D.
Simon, J. S.
Scott, J. W.
Tsai, Y. C. Cincia
Zimmerman, A. M.
Halperin, W. P.
contents We perform cluster aggregation simulations to model the structure of anisotropic aerogel. By biasing the diffusion process, we are able to obtain two distinct types of globally anisotropic aerogel structures which we call "nematic", with long strands along the anisotropy axis, and "planar", with long strands in planes perpendicular to the anisotropy axis. We calculate the auto-correlation function, the structure factor, and the angular dependence of the free-path distribution for these samples. The calculated structure factor from simulated aerogels can be compared with data from small-angle X-ray scattering (SAXS) of lab-grown aerogel allowing us to classify the spatial structure of the lab-grown samples. We find that the simulated "nematic" aerogel has a structure factor consistent with lab-grown, axially-compressed silica aerogel while the simulated "planar" aerogel has a structure factor consistent with lab-grown "stretched" silica aerogel. Unexpectedly, compressing previously isotropic silica aerogel leads to the formation of long strands along the compression axis while stretching silica aerogel leads to formation of planes perpendicular to the stretching axis. We discuss the implication of this determination on experiments of superfluid $^3$He in anisotropic aerogel, in particular the orbital analog of the spin-flop transition.
format Preprint
id arxiv_https___arxiv_org_abs_2301_11261
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Planar and Nematic Aerogels: DLCA and Superfluid 3He
Nguyen, M. D.
Simon, J. S.
Scott, J. W.
Tsai, Y. C. Cincia
Zimmerman, A. M.
Halperin, W. P.
Materials Science
Soft Condensed Matter
Superconductivity
We perform cluster aggregation simulations to model the structure of anisotropic aerogel. By biasing the diffusion process, we are able to obtain two distinct types of globally anisotropic aerogel structures which we call "nematic", with long strands along the anisotropy axis, and "planar", with long strands in planes perpendicular to the anisotropy axis. We calculate the auto-correlation function, the structure factor, and the angular dependence of the free-path distribution for these samples. The calculated structure factor from simulated aerogels can be compared with data from small-angle X-ray scattering (SAXS) of lab-grown aerogel allowing us to classify the spatial structure of the lab-grown samples. We find that the simulated "nematic" aerogel has a structure factor consistent with lab-grown, axially-compressed silica aerogel while the simulated "planar" aerogel has a structure factor consistent with lab-grown "stretched" silica aerogel. Unexpectedly, compressing previously isotropic silica aerogel leads to the formation of long strands along the compression axis while stretching silica aerogel leads to formation of planes perpendicular to the stretching axis. We discuss the implication of this determination on experiments of superfluid $^3$He in anisotropic aerogel, in particular the orbital analog of the spin-flop transition.
title Planar and Nematic Aerogels: DLCA and Superfluid 3He
topic Materials Science
Soft Condensed Matter
Superconductivity
url https://arxiv.org/abs/2301.11261