Mujahid Aziz | Engineering | Best Researcher Award

Published on by Research Awards

Prof. Mujahid Aziz | Engineering | Best Researcher Award

Cape Peninsula University of Technology | South Africa

Professor Mujahid Aziz is a distinguished academic and research leader serving as the Assistant Dean: Learning & Teaching in the Faculty of Engineering and the Built Environment (FEBE) at the Cape Peninsula University of Technology (CPUT) in South Africa. In this leadership role, he oversees and enhances academic excellence across eight departments within the faculty, which collectively serve nearly 10,000 students, including a growing cohort of postgraduate scholars. As a champion of academic transformation, Prof. Aziz is deeply committed to promoting innovative teaching practices, curriculum modernization, and student-centered learning within engineering education. His leadership is instrumental in aligning the faculty’s academic strategies with industry relevance, sustainability goals, and the national development agenda. With over 23 years of experience as an Associate Professor of Chemical Engineering, Prof. Aziz has established himself as a transformative educator, researcher, and mentor. His academic journey reflects a sustained dedication to advancing both the theoretical and practical dimensions of environmental and chemical engineering. Throughout his career, he has supervised numerous postgraduate students and contributed to the development of engineering curricula that integrate sustainability, innovation, and applied research. His pedagogical philosophy emphasizes experiential learning and the development of problem-solving skills essential for addressing real-world engineering challenges, particularly in water and environmental systems. As the Principal Investigator of the Environmental Engineering Research Group (EERG), Prof. Aziz leads multidisciplinary research focused on sustainable water and wastewater treatment technologies. His work is internationally recognized, with publications in high-impact journals such as Desalination, MDPI Membranes, MDPI Water, and Environmental Processes. Recent research endeavors have explored cutting-edge methods for biofouling mitigation in polyamide thin-film composite reverse osmosis membranes, particularly through polymer grafting and nanoparticle coating. These innovations are pivotal for improving the treatment of municipal bioreactor secondary effluent and enhancing the efficiency and longevity of membrane systems used in desalination and wastewater reuse. Prof. Aziz’s research portfolio is characterized by a strong interdisciplinary approach that bridges materials science, chemical process design, and environmental sustainability. His areas of specialization encompass membrane technology, wastewater reuse, electrochemical and adsorption processes, brine management, and zero liquid discharge (ZLD) systems. His work addresses critical environmental challenges associated with water scarcity and industrial pollution, offering viable pathways for circular water economies and resource recovery. His pursuit of innovation in micropollutant removal, membrane fouling control, and electro-oxidation for water reuse reflects his vision of achieving sustainable and intelligent environmental engineering solutions. Through his academic leadership, pioneering research, and commitment to mentorship, Prof. Mujahid Aziz continues to make a profound impact on the future of engineering education and sustainable water technology development in South Africa and beyond.

Profiles: Orcid | Google Scholar

Featured Publications

Aziz, M., & Ojumu, T. (2020). Exclusion of estrogenic and androgenic steroid hormones from municipal membrane bioreactor wastewater using UF/NF/RO membranes for water reuse application. Membranes, 10(3), 37. https://doi.org/10.3390/membranes10030037

Aziz, M., & Kasongo, G. (2021). The removal of selected inorganics from municipal membrane bioreactor wastewater using UF/NF/RO membranes for water reuse application: A pilot-scale study. Membranes, 11(2), 1–14. https://doi.org/10.3390/membranes11020104

Myburgh, D. P., Aziz, M., Roman, F., Jardim, J., & Chakawa, S. (2019). Removal of COD from industrial biodiesel wastewater using an integrated process: Electrochemical oxidation with IrO₂–Ta₂O₅/Ti anodes and chitosan powder. Environmental Processes, 6(4), 819–840. https://doi.org/10.1007/s40710-019-00393-5

Kasongo, G., Steenberg, C., Morris, B., Kapenda, G., Jacobs, N., & Aziz, M. (2019). Surface grafting of polyvinyl alcohol (PVA) cross-linked with glutaraldehyde (GA) to improve resistance to fouling of aromatic polyamide thin film composite reverse osmosis membranes. Water Practice & Technology, 14(3), 614–624. https://doi.org/10.2166/wpt.2019.042

Chakawa, S., & Aziz, M. (2021). Investigating the result of current density, temperature, and electrolyte concentration on COD subtraction of petroleum refinery wastewater using response surface methodology. Water, 13(6), 835. https://doi.org/10.3390/w13060835

Aziz, M., & Kasongo, G. (2019). Scaling prevention of thin film composite polyamide reverse osmosis membranes by Zn ions. Desalination, 464, 76–83. https://doi.org/10.1016/j.desal.2019.04.006

Chinedu Okere | Engineering | Best Researcher Award

Published on by Research Awards

Dr. Chinedu Okere | Engineering | Best Researcher Award 

University of Houston | United States

Dr. Chinedu (Junior) Okere is a dynamic early-career researcher whose interests span subsurface hydrogen generation, large-scale hydrogen storage in geological formations, experimental and numerical modelling of CO₂ capture, utilisation and storage (CCUS), methane leakage from orphaned wells, and drilling/fracturing fluid design and formation-damage mitigation in petroleum reservoirs. His professional trajectory has taken him from graduate research at the China University of Petroleum (Beijing) (M.Eng., 2022) to doctoral studies at the Texas Tech University (Ph.D., 2025) and onward to a post-doctoral appointment in the Department of Petroleum Engineering at the University of Houston (from mid-2025). In these roles he has supervised PhD students, managed a U.S. Department of Energy-funded CarbonSAFE project on CO₂ storage, and led the development of grant proposals, patents and peer-reviewed publications. According to his Google Scholar profile he has to date achieved 659 citations and an h-index of 15, with an i10-index of 19. His publication record includes a broad spectrum of articles (20+, depending on counting method) covering topics from “clean hydrogen generation from petroleum reservoirs” to fuzzy-ball fluid‐induced damage in tight reservoirs, reservoir suitability for hydrogen storage, and methane leakage from abandoned wells. Most recently, his first‐author papers (2024-2025) address techno-economic feasibility of in-situ hydrogen production from petroleum reservoirs, SARA-based experimental and numerical investigations of in-situ hydrogen generation, and comparative numerical studies for optimisation of hydrogen production and CCUS strategies. In recognition of his impact he has received numerous honours including the 2024 International Inventions Awards – Hydrogen Energy Best Researcher Award, and the Society of Petroleum Engineers Permian Basin Scholarship. With strong interdisciplinary credentials spanning petroleum engineering, energy systems, reservoir simulation, and hydrogen/CCUS technologies, Dr. Okere stands out as an emerging scholar bridging the conventional oil-&-gas domain with the clean/hydrogen energy transition. His h-index of 15 reflects a solid early‐career impact: it means he has at least 15 publications each cited at least 15 times. (The h-index concept was originally proposed by J. E. Hirsch as a simple measure of productivity and citation impact. Going forward, his strong publication momentum, growing citation base and leadership in grant/industry-adjacent projects suggest that he is well-positioned to further increase both his research output and influence in the hydrogen/CCUS engineering community.

Profiles: Scopus | Orcid | Google Scholar 

Featured Publications

Okere, C. J., & Sheng, J. J. (2023). Review on clean hydrogen generation from petroleum reservoirs: Fundamentals, mechanisms, and field applications. International Journal of Hydrogen Energy, 101.

Edouard, M. N., Okere, C. J., Ejike, C., Dong, P., & Suliman, M. A. M. (2023). Comparative numerical study on the co-optimization of CO₂ storage and utilization in EOR, EGR, and EWR: Implications for CCUS project development. Applied Energy, 347, 121448.

Eyitayo, S. I., Okere, C. J., Hussain, A., Gamadi, T., & Watson, M. C. (2024). Synergistic sustainability: Future potential of integrating produced water and CO₂ for enhanced carbon capture, utilization, and storage (CCUS). Journal of Environmental Management, 351, 119713.

He, J., Okere, C. J., Su, G., Hu, P., Zhang, L., Xiong, W., & Li, Z. (2021). Formation damage mitigation mechanism for coalbed methane wells via refracturing with fuzzy-ball fluid as temporary blocking agents. Journal of Natural Gas Science and Engineering, 90, 103956.

Okere, C. J., Su, G., Zheng, L., Cai, Y., Li, Z., & Liu, H. (2020). Experimental, algorithmic, and theoretical analyses for selecting an optimal laboratory method to evaluate working fluid damage in coal bed methane reservoirs. Fuel, 282, 118513.

Tao, X., Okere, C. J., Su, G., & Zheng, L. (2022). Experimental and theoretical evaluation of interlayer interference in multi-layer commingled gas production of tight gas reservoirs. Journal of Petroleum Science and Engineering, 208, 109731.

Okere, C. J., & Sheng, J. J. (2024). A new modelling approach for in-situ hydrogen production from heavy oil reservoirs: Sensitivity analysis and process mechanisms. Energy, 302, 131817.

Opara, S. U., & Okere, C. J. (2024). A review of methane leakage from abandoned oil and gas wells: A case study in Lubbock, Texas, within the Permian Basin. Energy Geoscience, 5(3), 100288.