Environmentally benign three-dimensional aerogels for air filtration and the mechanisms
In this PhD study, three-dimensional (3D), robust and highly-porous aerogels were employed as air filters because their large internal volume could promote higher removal efficiency of particulate matter (PM), especially for ultrafine particles, while their ultrahigh porosity could facilitate rel...
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| Format: | Thesis-Doctor of Philosophy |
| Language: | English |
| Published: |
Nanyang Technological University
2021
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| Online Access: | https://hdl.handle.net/10356/146137 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | In this PhD study, three-dimensional (3D), robust and highly-porous aerogels were
employed as air filters because their large internal volume could promote higher
removal efficiency of particulate matter (PM), especially for ultrafine particles,
while their ultrahigh porosity could facilitate relatively low pressure drops (Ps).
This synergistic behavior of aerogel filters could effectively address the efficiency-
P trade-off of conventional fibrous filters. The aerogels can be categorized as
fibrous and non-fibrous, and they can be fabricated via two separate different
methods: (1) freeze-drying in a mold or (2) ice-crystals-induced templating method.
Apart from the intrinsic structures of the starting materials, the fabrication method
adopted would determine the final microstructure of the aerogels. In short, the
aerogels prepared in this work would possess either isotropic or aligned porous
architectures. Nevertheless, a potential drawback of highly porous 3D aerogels is
their relatively poor structural stabilities, which hinders their practical applications
as air filters due to the constant compressive force exerted by the airflow in the
filtration process. This problem may be overcome by employing chemically- or
physically-induced cross-linking to reinforce the aerogel structure. Hence, the
structures and morphologies of the aerogels would greatly affect the filtration
performance of these aerogel filters. Thus, the aim of this thesis is to prepare highly
robust 3D aerogel air filters and investigate the effects of the microstructures on the
filtration performance as well as the respective underlying filtration mechanisms of
the different as-prepared aerogels.
Three aerogel systems were adopted in this thesis study; (1) PLLA/PDLA blend
stereocomplex nanofibers, (2) biomass-based lignin with graphene as reinforcement
agent (3) lignin reinforcement agent and cellulose nanofibers. We report that highlyrobust
aerogels, both fibrous and non-fibrous, with either isotropic or preferably
aligned pores are successfully fabricated via different facile cross-linking
approaches; spontaneous inter-fiber stereocomplexation-induced cross-linking for
Abstract
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the PLLA/PDLA blend system while thermal treatment was adopted for the other
remaining systems. For each system, it is demonstrated that the extent of crosslinking
can be easily controlled by adjusting the microstructures and macroscopic
shapes of the aerogels, which could influence the filtration performance of the
various aerogels. Furthermore, as compared to conventional compact fibrous filters,
all the as-prepared aerogel filters demonstrated higher overall filtration efficiency
accompanied with a significantly lower ΔP. Through this work, it is believed that the
understandings derived can serve as a guideline to facilely fabricate highly-robust
and efficient filters for various air filtration applications. |
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