Your search keyword '"Guo, Zunmin"' showing total 4 results

1. Porous silica nanosheets in PIM-1 membranes for CO2 separation.

Author

Mohsenpour, Sajjad, Guo, Zunmin, Almansour, Faiz, Holmes, Stuart M., Budd, Peter M., and Gorgojo, Patricia

Subjects

*POROUS silica, *MEMBRANE separation, *NANOSTRUCTURED materials, *SEPARATION of gases, *CARBON dioxide, *CARBON sequestration

Abstract

PIM-1-based freestanding mixed matrix membranes (MMMs) and thin film nanocomposites (TFNs) were prepared by incorporating porous silica nanosheets (SN) and exfoliated SN (E-SN) derived from natural vermiculite (Verm) in the PIM-1 polymer matrix. In addition, SN were functionalized by sulfonic acid and amine groups (S-SN and N-SN, respectively) and were also used as fillers for the preparation of MMMs. The gas separation performance was evaluated using CO 2 /CH 4 and CO 2 /N 2 (1:1, v:v) binary gas mixtures. Among freestanding membranes, fresh ones (i.e. tested right after preparation) containing 0.05 wt% functionalized SN and E-SN outperformed the neat PIM-1, surpassing the 2008 Robeson upper bound. At the same filler concentration, fresh MMMs with sulfonic acid-functionalized SN (S-SN) exhibited 40% higher CO 2 permeability, 20% higher CO 2 /N 2 selectivity and almost the same CO 2 /CH 4 selectivity as neat PIM-1 membranes. Moreover, after 150 days of aging, these membranes were capable of maintaining up to 68% of their initial CO 2 permeability (compared to 37% for neat PIM-1). When prepared as TFN membranes, the incorporation of 0.05 wt% of S-SN led to 35% higher initial CO 2 permeance and five times higher CO 2 permeance after 28 days. [Display omitted] • Freestanding and thin PIM-1-based films were fabricated using silica nanosheets (SNs). • The prepared MMMs and TFNs were tested for CO 2 /N 2 and CO 2 /CH 4 separation. • PIM-1/sulfonated SNs (0.05 wt%) showed the best initial performance. • The incorporation of SNs partially prevented aging in both TFNs and MMMs. [ABSTRACT FROM AUTHOR]

Published

2022

2. Insights into the performance and degradation of polybenzimidazole/muscovite composite membranes in high–temperature proton exchange membrane fuel cells.

Author

Guo, Zunmin, Chen, Jianuo, Byun, Jae Jong, Perez–Page, Maria, Ji, Zhaoqi, Zhao, Ziyu, and Holmes, Stuart M.

Subjects

*PROTON exchange membrane fuel cells, *COMPOSITE membranes (Chemistry), *MUSCOVITE, *POWER density

Abstract

To improve the performance and durability of phosphoric acid (PA) doped polybenzimidazole (PBI) membranes in high–temperature proton exchange membrane fuel cells (HT–PEMFCs), in this work, as–received natural muscovite (Mus), a clay material, was successfully incorporated into PBI matrix as an inorganic filler through the doctor blade method. The amount of Mus was varied (0.5–2 wt%) to explore its impact on the proton conductivity, mechanical and dimensional stability, power density, durability, and acid retention ability of the composite membranes. As the incorporation of Mus into membranes can introduce interactions with polymer chains and PA molecules to afford additional proton transport pathways at the interfaces in Mus–PBI and Mus–PA crosslinks, the membrane with 1 wt% Mus showed highest power density of 586 mW cm−2 at 150 °C without humidification, 24% higher than the pure PBI membrane (474 mW cm−2). Meanwhile, the PA doped composite membrane with 1 wt% Mus also displayed the highest mechanical strength (7.5 MPa) and lowest dimensional swelling (70.99% in area swelling and 202% in volume swelling). Compared with the pristine PBI membrane, the composite membranes had significantly improved durability under accelerated stress test (AST). The decreased ohmic resistance and increased polarization resistance after AST are related to the membrane thinning and the loss of catalyst active area, respectively. Most importantly, it was found that the strong interactions between Mus and PA molecules lead to improved acid retention ability of the composite membranes, thus less leached acid from the composite membrane reduces the negative effects on the catalyst degradation to alleviate degradation on cell performance and durability. [Display omitted] • Natural muscovite was successfully incorporated into PBI membranes using the doctor blade method. • The prepared composite membranes show better power density and durability than the pure PBI membrane. • The interactions between Mus and PA explored by EDS, TGA and XPS benefit improved acid retention ability. [ABSTRACT FROM AUTHOR]

Published

2022

3. Operando synchrotron-based X-ray study and intervention approaches of graphene-related-materials for investigating the performance and durability of HT-PEMFC.

Author

Chen, Jianuo, Perez-Page, Maria, Parlett, Christopher M.A., Guo, Zunmin, Yang, Xiaochen, Zhou, Zeyu, Zhai, Heng, Bartlett, Stuart, Miller, Thomas S., and Holmes, Stuart M.

Subjects

*X-ray absorption near edge structure, *PROTON exchange membrane fuel cells, *SYNCHROTRONS, *X-ray fluorescence, *X-ray spectroscopy, *X-ray absorption

Abstract

• Operando synchrotron X-ray study on Phosphorus and Platinum migration. • Graphene-related-material applied as interventional materials for comparison. • X-ray Absorption Near Edge Structure applied to study chemical structural change. • Conducting mechanistic studies via the three-phase interface. • Performance and durability of high-temperature proton exchange membrane fuel cells. The application of high-temperature proton exchange membrane fuel cells (HT-PEMFCs) addresses challenges in water management, fuel purity, and overheating under high current density. However, phosphoric acid (PA) migration hinders their development. This study uses synchrotron-based X-ray fluorescence spectroscopy to investigate PA and catalyst migration. Interventions with single-layer graphene and electrochemically exfoliated graphene oxide improve performance and durability. X-ray absorption spectroscopy provides insights into relevant mechanisms, advancing understanding of membrane electrode assembly preparation and the intricate influences of PA and catalyst migration on performance and durability in HT-PEMFCs. [ABSTRACT FROM AUTHOR]

Published

2024

4. One step electrochemical exfoliation of natural graphite flakes into graphene oxide for polybenzimidazole composite membranes giving enhanced performance in high temperature fuel cells.

Author

Chen, Jianuo, Perez-Page, Maria, Ji, Zhaoqi, Zhang, Zhe, Guo, Zunmin, and Holmes, Stuart

Subjects

*COMPOSITE membranes (Chemistry), *GRAPHENE oxide, *GRAPHITE, *PROTON exchange membrane fuel cells, *FUEL cells, *HIGH temperatures, *ELECTROLYTE solutions

Abstract

In this work, a 3D-printed reactor was designed to enable natural graphite flakes to be used for electrochemical exfoliation to quickly obtain graphene oxide. Graphite foil as a typical raw material of electrochemical exfoliation was also exfoliated for comparison. Under the same conditions (10 V, 1 mol L-1 ammonium sulphate solution as electrolyte), the graphene products obtained by one-step electrochemical exfoliation using natural graphite flakes based on the reactor, have a significantly higher degree of oxidation than products obtained using graphite foil (the oxygen content is increased by 50.2%). In addition, the degree of oxidation can be further increased by increasing the electrolyte concentration or reaction time. This design achieves one-step exfoliation using natural graphite flakes to obtain graphene oxide with tunable oxygen content in short time without using any strong oxidants or strong acids. The as-prepared electrochemically exfoliated graphene oxide (EGO) was used to prepare polybenzimidazole (PBI)/graphene oxide (GO) composite membranes for high-temperature polymer electrolyte membrane fuel cells (HTPEMFC). The 0.5%, 1% and 2% EGO loadings in the PBI membrane increased the peak power density by 13.8%, 24.4% and 29.2%, respectively. Image 1 • The use of natural graphite flakes as raw materials for electrochemical exfoliation. • No oxidant and acid used to obtain graphene oxide. • A novel reactor design achieves the above goals. • Electrochemically exfoliated graphene oxide enhances the performance of PBI membrane. [ABSTRACT FROM AUTHOR]

Published

2021