Preparation and Characterization of Polyimide Aerogels with a Uniform Nanoporous Framework

Zhong, Ya; Kong, Yong; Chen, Ying; Li, Boya; Wu, Xiaodong; Liu, Sijia; Shen, Xiaodong; Cui, Sheng

doi:10.1021/acs.langmuir.8b01756

Cited by 28 publications

(14 citation statements)

References 54 publications

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“…The welded PI-NFAs with various densities (0.96–16.14 mg/cm 3 ) were prepared simply by adjusting the concentrations of the nanofiber dispersions, and their porosities are listed in Table S3. Plotting the porosities of various PI aerogels (sol–gel-derived PI aerogels ,,− and nanofiber-based PI aerogels ,− ) versus their density revealed that the welded PI-NFAs fabricated in this study processed much lower density and higher porosity compared to the sol–gel-derived PI aerogels and nanofiber-based PI aerogels strengthened by cross-linkers (as shown in Figure d).…”

Section: Resultsmentioning

confidence: 80%

Solvent Vapor Strengthened Polyimide Nanofiber-Based Aerogels with High Resilience and Controllable Porous Structure

Shen

Wang

Liu

et al. 2020

ACS Appl. Mater. Interfaces

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Owing to the hierarchically three-dimensional (3D) network, ultralow density, and high porosity, nanofiber-based aerogels (NFAs) have drawn great attention recently. However, precise control of the porous structure and mechanical properties of NFAs, which have been proved to be extremely essential to the applications, still remains a major challenge. Herein, electrospun polyimide (PI) nanofibers were utilized as building blocks to construct NFAs through the solid-templating technique. The porous structure of PI nanofiber-based aerogels (PI-NFAs) could be adjusted by changing the processing parameters. By further welding the adjacent nanofibers at the contact sites with solvent vapor, high-resilience PI-NFAs were successfully prepared with comparable or higher recoverable, under compression, folding and torsion relative to other NFAs. The welded PI-NFAs showed ultralow density (minimum of 0.96 mg/cm3), high porosity (maximum of 99.93%), and tunable hierarchical structure. Therefore, this study brought a new perspective on the simple preparation of high-resilience nanofiber-based aerogels with tunable porous structures.

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Section: Resultsmentioning

confidence: 80%

Solvent Vapor Strengthened Polyimide Nanofiber-Based Aerogels with High Resilience and Controllable Porous Structure

Shen

Wang

Liu

et al. 2020

ACS Appl. Mater. Interfaces

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“…CO 2 clathrate hydrates are involved in current potential applications in sustainable industries, such as CO 2 capture technologies, that are necessary to be developed to store this greenhouse gas [1–12] . Thus, both scientific and technological communities, from different fields of chemistry, physics, geology, engineering, etc., have devoted numerous collaborative research efforts, involving investigations at microscopic level using molecular simulation tools, as several processes (hydrate nucleation or growth or cage occupancy) could get hardly accessible though experimentation [12–23] .…”

Section: Introductionmentioning

confidence: 99%

Exploring CO₂@sI Clathrate Hydrates as CO₂ Storage Agents by Computational Density Functional Approaches

et al. 2021

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The formation of specific clathrate hydrates and their transformation at given thermodynamic conditions depends on the interactions between the guest molecule/s and the host water lattice. Understanding their structural stability is essential to control structure‐property relations involved in different technological applications. Thus, the energetic aspects relative to CO2@sI clathrate hydrate are investigated through the computation of the underlying interactions, dominated by hydrogen bonds and van der Waals forces, from first‐principles electronic structure approaches. The stability of the CO2@sI clathrate is evaluated by combining bottom‐up and top‐down approaches. Guest‐free and CO2 guest‐filled aperiodic cages, up to the gradually CO2 occupation of the entire sI periodic unit cells were considered. Saturation, cohesive and binding energies for the systems are determined by employing a variety of density functionals and their performance is assessed. The dispersion corrections on the non‐covalent interactions are found to be important in the stabilization of the CO2@sI energies, with the encapsulation of the CO2 into guest‐free/empty cage/lattice being always an energetically favorable process for most of the functionals studied. The PW86PBE functional with XDM or D3(BJ) dispersion corrections predicts a lattice constant in accord to the experimental values available, and simultaneously provides a reliable description for the guest‐host interactions in the periodic CO2@sI crystal, as well as the energetics of its progressive single cage occupancy process. It has been found that the preferential orientation of the single CO2 in the large sI crystal cages has a stabilizing effect on the hydrate, concluding that the CO2@sI structure is favored either by considering the individual building block cages or the complete sI unit cell crystal. Such benchmark and methodology cross‐check studies benefit new data‐driven model research by providing high‐quality training information, with new insights that indicate the underlying factors governing their structure‐driven stability, and triggering further investigations for controlling the stabilization of these promising long‐term CO2 storage materials.

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“…Due to their unique properties, aerogels have been used in adsorption [ 4 , 5 ], catalysts, supercapacitors [ 6 , 7 ], sensors [ 8 ], energy storage [ 9 ], and so forth. Over the past few decades, aerogels made from polymer have been developed, such as phenol-formaldehyde resin [ 10 ], polyurethanes [ 11 ], polyureas [ 12 ], polyamides [ 13 ], and polyimide [ 14 ]. Compared to other aerogels, PI aerogels attracted more attention from researchers due to perfect chemical stability [ 15 ], good mechanical properties [ 16 ], perfect dielectric performance [ 17 , 18 ] and high decomposition temperatures [ 19 , 20 ].…”

Section: Introductionmentioning

confidence: 99%

Mechanically Strong and Tailorable Polyimide Aerogels Prepared with Novel Silicone Polymer Crosslinkers

Zhang

Deng

Lun

et al. 2022

Gels

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Polyimide (PI) aerogels were prepared using self-designed silicone polymer cross-linkers with multi-amino from low-cost silane coupling agents to replace conventional small-molecule cross-linkers. The long-chain structure of silicone polymers provides more crosslinking points than small-molecule cross-linkers, thus improving the mechanical properties of polyimide. To investigate the effects of amino content and degree of polymerization on the properties of silicone polymers, the different silicone polymers and their cross-linked PI aerogels were prepared. The obtained PI aerogels exhibit densities as low as 0.106 g/cm3 and specific surface areas as high as 314 m2/g, and the maximum Young’s modulus of aerogel is up to 20.9 MPa when using (T-20) as cross-linkers. The cross-linkers were an alternative to expensive small molecule cross-linkers, which can improve the mechanical properties and reduce the cost of PI aerogels.

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Preparation and Characterization of Polyimide Aerogels with a Uniform Nanoporous Framework

Cited by 28 publications

References 54 publications

Solvent Vapor Strengthened Polyimide Nanofiber-Based Aerogels with High Resilience and Controllable Porous Structure

Solvent Vapor Strengthened Polyimide Nanofiber-Based Aerogels with High Resilience and Controllable Porous Structure

Exploring CO₂@sI Clathrate Hydrates as CO₂ Storage Agents by Computational Density Functional Approaches

Mechanically Strong and Tailorable Polyimide Aerogels Prepared with Novel Silicone Polymer Crosslinkers

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Preparation and Characterization of Polyimide Aerogels with a Uniform Nanoporous Framework

Cited by 28 publications

References 54 publications

Solvent Vapor Strengthened Polyimide Nanofiber-Based Aerogels with High Resilience and Controllable Porous Structure

Solvent Vapor Strengthened Polyimide Nanofiber-Based Aerogels with High Resilience and Controllable Porous Structure

Exploring CO2@sI Clathrate Hydrates as CO2 Storage Agents by Computational Density Functional Approaches

Mechanically Strong and Tailorable Polyimide Aerogels Prepared with Novel Silicone Polymer Crosslinkers

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Exploring CO₂@sI Clathrate Hydrates as CO₂ Storage Agents by Computational Density Functional Approaches