doi: 10.1021/acs.langmuir.2c02696.
Epub 2023 Jan 27.
Macroporous Polyimide Aerogels: A Comparison between Powder Microparticles Synthesized via Wet Gel Grinding and Emulsion Processes
Affiliations
- PMID: 36706272
- PMCID: PMC9910053
- DOI: 10.1021/acs.langmuir.2c02696
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Macroporous Polyimide Aerogels: A Comparison between Powder Microparticles Synthesized via Wet Gel Grinding and Emulsion Processes
Langmuir.
.
Abstract
It is noteworthy to mention that synthesizing the polyimide aerogel powder, which is carried out in this study, benefits from two advantages: (i) the powder particles can be used for some specific applications where the monolith is not suitable and (ii) there is a possibility to investigate how a polyimide aerogel monolith can be made through the polyimide powder to reduce its cost and cycle time. In this study, two straightforward methods, wet gel grinding and emulsion, are introduced to prepare polyimide aerogel powders using ambient pressure drying. The microscopic properties of interest, including skeletal and porous structures, microparticle size and assembly, combined with macroscopic properties such as thermal stabilities and conductivities (0.039 W/m·K), confirm that the fabricated microparticles with a size in the range of 7-20 μm and porosity in the range of 65-85% are thermally stable up to 500 °C.
Conflict of interest statement
The authors declare no competing financial interest.
Figures
PAA: polyamic acid
(resin); WGG:
wet gel grinding; EM: emulsion; PI-WGG: polyimide aerogel powders
by WGG; PI-EM: polyimide aerogel powders by EM.
Particle size distribution for PI-WGG
powders at different dilution
ratios.
SEM for PI-WGG powders with DMSO/PAA ratios of (a) 0.0,
(b) 0.5,
(c) 1.0, and (d) 1.5.
Particle size distribution for PI-EM powders at different dilution
ratios.
SEM images for PI-EM powders with DMSO/PAA ratios of (a)
0.0, (b)
0.5, (c) 1.0, and (d) 1.5.
Pore size distributions
of PI-WGG powders were measured using (a)
N2 sorption and (b) MIP.
Pore size distributions of PI-EM powders were measured
by (a) N2 sorption and (b) MIP.
Porosity–density
profiles for PI-WGG and PI-EM powders.
% Weight as a function of temperature for (a) PI-WGG and (b) PI-EM
powders.
Thermal conductivity–density profiles
for (a) PI-WGG and
(b) PI-EM powders.
Correlation of thermal conductivity and dilution ratio
for (a)
PI-WGG and (b) PI-EM.
Correlation
of thermal conductivity and pore size for PI-EM.
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