Full research article

Large-area silica aerogel for use as Cherenkov radiators with high refractive index, developed by supercritical carbon dioxide drying

Makoto Tabataa,∗, Ichiro Adachib, Yoshikiyo Hatakeyamac, Hideyuki Kawaia, Takeshi Moritac, Takayuki Sumiyoshid

aDepartment of Physics, Chiba University, Chiba, Japan

bInstitute of Particle and Nuclear Studies (IPNS), High Energy Accelerator Research Organization (KEK), Tsukuba, Japan

cGraduate School of Advanced Integration Science, Chiba University, Chiba, Japan

dDepartment of Physics, Tokyo Metropolitan University, Hachioji, Japan

The Journal of Supercritical Fluids, Volume 110, Pages 183-192, April 2016, Elsevier B.V.


JCR categories:

Engineering, Chemical

Chemistry, Physical


Scopus subject area:

Chemical Engineering: General Chemical Engineering

Physics and Astronomy: Condensed Matter Physics

Chemistry: Physical and Theoretical Chemistry


Received 20 October 2015

Revised 25 November 2015

Accepted 26 November 2015

First published online 1 December 2015


DOI:10.1016/j.supflu.2015.11.022

arXiv:1701.00143 [physics.ins-det]



Citations

Citing papers (13)

Excluding self-citations (8)

Journal articles only (9)

Journal articles only excluding self-citations (7)


  1. Performance and commissioning of HAPDs in the Aerogel RICH counter

    M. Yoenaga et al., Nuclear Instruments and Methods in Physics Research A, Volume xxx, Pages xxx-xxx, Xxx 2019, in press

    (Self-citation)


  2. Status of high-quality silica aerogel radiators

    I. Adachi, Nuclear Instruments and Methods in Physics Research A, Volume xxx, Pages xxx-xxx, Xxx 2019, in press


  3. Transparent tiles of silica aerogels for high-energy physics (Book Chapter)

    M. Tabata, in Springer Handbook of Aerogels (2nd ed.), Pages xxx-xxx, Xxx 2019, in press

    (Self-citation)


  4. Effects of reaction parameters on the preparation of P4VP/SiO2 composite aerogel via supercritical CO2 drying

    X. Yang et al., Polymer Composites, Volume xxx, Pages xxx-xxx, Xxx 2019, in press


  5. Assembly of a silica aerogel radiator module for the Belle II ARICH system (Conference Proceedings)

    M. Tabata et al., Springer Proceedings in Physics, Volume 212, Pages 253-256, August 2018

    (Self-citation)


  6. Development of slow control system for the Belle II ARICH counter (Conference Proceedings)

    M. Yonenaga et al., Springer Proceedings in Physics, Volume 212, Pages 46-49, August 2018

    (Self-citation)


  7. Kinetics of supercritical drying of gels (Review)

    İ. Şahin et al., Gels, Volume 4, Issue 1, Article number 3, March 2018


  8. Multifunctional hybrid aerogels: Hyperbranched polymer-trapped mesoporous silica nanoparticles for sustained and prolonged drug release

    H. D. M. Follmann et al., Nanoscale, Volume 10, Issue 4, Pages 1704-1715, January 2018


  9. Construction of silica aerogel radiator system for Belle II RICH Counter

    I. Adachi et al., Nuclear Instruments and Methods in Physics Research A, Volume 876, Pages 129-132, December 2017

    (Self-citation)


  10. Robust urethane-bridged silica aerogels available for water-carved aerosculptures

    Y. Zhang et al., New Journal of Chemistry, Volume 41, Issue 5, Pages 1953-1958, March 2017


  11. Low density and hydrophobic silica aerogels dried under ambient pressure using a new co-precursor method

    M. Li et al., Journal of Non-Crystalline Solids, Volume 452, Pages 187-193, November 2016


  12. A continuous extraction and pumpless supercritical CO2 drying system for laboratory-scale aerogel production (Technical note)

    I. Lázár and I. Fábián, Gels, Volume 2, Issue 4, Article number 26, October 2016


  13. Silica aerogels doped with MWCNT, Graphene, MoS2, and WS2

    E. A. Baum and C. A. Richards, in Electronic Projects Collection, Worcester Polytechnic Institute, E-project-032516-135049, March 2016

    (Institutional report)