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Design and development of unconventional catalytic conversion processes using electrons, photons, and microorganisms

Problem statement

Our long-term commitment to sustainability and a circular carbon economy involves unconventional catalytic conversion processes. We study various processes assisted by electrons, photons, or microorganisms to produce biofuels, chemicals, electricity, or treated water. For example, bio-electro-chemical systems, including microbial fuel cells (MFCs), electrolysis cells (MECs), and photo-assisted cells (PA-MECs), are promising technologies to simultaneously produce renewable energy and clean wastewater using active microorganisms as biocatalysts.

Our work aims to synthesize multi-functional catalysts and reactors to enhance electrical conductivity, photo-efficiency, microbiological affinity, porosity, hydrophilicity, and surface area for carbonaceous electrodes. We work with materials such as graphene oxide, metallic nanoparticles, nitride and carbide basic materials, and MXenes.

We consider new platform technologies to produce renewable biofuel and chemicals and treat wastewater using the nanotechnology and reaction engineering approach as an innovative combination to increase the productivity of these processes.

Goals

  • Develop and scale up electro-photo-bio-catalyst and -reactors
  • Propose novel processes to clean wastewater and produce electricity, chemicals, and bio-hydrogen
  • Model and simulate fuel cell performance
  • Use innovative catalysts (anode and cathode material) and reactor designs to improve fuel cell performance
EPB2023

Related People

Hend Omar Mohamed
Muhammad Arief Shafarifky
Pewee Datoo Kolubah
Rushana Khairova

Related Publications

Dual function sMoS2-cellulose/PVDF-based membrane for energy generation and pollutant removal

by Palanisamy, Kolubah, Im, Thangarasu, Hari, Saikaly, Mohamed, Castaño, Oh
Chem. Eng. J. Year: 2024 DOI: https://doi.org/10.1016/j.cej.2024.154597

Abstract

Fostering the creation of clean energy technologies that eliminate gas emissions and positively impact the environment is vital for confronting the dual challenges of escalating energy demands and environmental contaminants. Membrane-based technologies have emerged as effective strategies for harvesting clean energy and practically purifying water from contaminated wastewater. Here, we show that polyvinylidene difluoride (PVDF) with functionalized molybdenum disulfide (sMoS2) and nanocellulose (NC) is an attractive membrane for single-chamber air cathode microbial fuel cells (MFCs). Compared with conventional proton exchange membranes, our membrane boosts power generation up to 48.5 mW m−2 and efficiently catalyzes sonocatalytic dye degradation with 96 % efficiency when treating wastewater. This performance is due to a relatively high hydrophilicity, ion exchange capacity (0.84 meq. g−1), and proton conductivity (1.03 × 10−2 S cm−1), combined with reduced oxygen permeability (27 × 1012 cm s−1) compared with conventional membranes. The synergy effect of the PVDF matrix and sMoS2 + NC promotes proton transfer, enhancing electricity generation and pollutant degradation. The membrane shows promising stability and mechanical properties, offering a viable membrane for improved energy recovery from wastewater treatment.

Keywords

EPB