Qingguo Ma | Chemical Engineering | Excellence in Innovation Award

Published on by Research Awards

Dr. Qingguo Ma | Chemical Engineering | Excellence in Innovation Award

Taiyuan Institute of Technology | China

Dr. Qingguo Ma, an accomplished Associate Professor at the Taiyuan Institute of Technology, is a distinguished researcher specializing in advanced wastewater treatment, particularly in the catalytic degradation of formaldehyde. With a doctoral degree obtained from the School of Chemical Engineering and Technology at Nanjing University of Science and Technology, Dr. Ma has established a focused research trajectory in the development of innovative and efficient oxidation-based solutions for industrial pollutant removal. His work emphasizes the use of advanced oxidation processes employing oxidants such as hydrogen peroxide and monopersulfate in conjunction with highly efficient catalytic systems, including transition metal oxides and lanthanum-based composite metal oxide catalysts. Through this research, Dr. Ma has successfully achieved remarkable improvements in formaldehyde degradation efficiency, notably demonstrating degradation rates exceeding 90% under ambient conditions without the need for acidic, alkaline, photochemical, or electrocatalytic environments. This breakthrough shortens the oxidative degradation time by up to 12 times compared to conventional heterogeneous catalysts and provides a scalable pathway toward cost-effective and energy-efficient wastewater treatment technologies. Dr. Ma’s academic contributions are supported by a robust research profile, including five completed or ongoing research projects, eleven patents published or under application, and thirteen peer-reviewed publications indexed in SCI databases. His work has attracted growing scholarly attention, reflected in a developing citation index and engagement in two consultancy or industry-linked research initiatives. As a member of the Shanxi Provincial Society for Inspection and Testing, he actively contributes to the advancement of environmental monitoring and chemical engineering practices within the professional community. His research further explores the mechanistic pathways of formaldehyde oxidation, identifying both radical-driven and non-radical catalytic routes, which enhances scientific understanding and offers new design concepts for catalytic materials used in environmental remediation. Dr. Ma continues to expand collaborations and strengthen knowledge transfer through academic platforms, contributing meaningfully to scientific and societal progress in pollution control. With demonstrated excellence, innovation, and commitment to advancing sustainable wastewater treatment technologies, he exemplifies the qualities recognized by the Excellence in Innovation Award. Dr. Ma affirms the authenticity and accuracy of all information included in this application and acknowledges the guidelines and terms set forth for this nomination.

Profiles: Scopus | Orcid

Featured Publications

Ma, Q. (2024). Preparation of perovskite-type LaMnO₃ and its catalytic degradation of formaldehyde in wastewater. Molecules, 29(16). https://doi.org/10.3390/molecules29163822

Ma, Q. (2023). Removal of formaldehyde in water with low concentration of hydrogen peroxide catalyzed by lanthanum–silicon oxide composite. Desalination and Water Treatment, 29734. https://doi.org/10.5004/dwt.2023.29734

Ma, Q. (2023). The Baeyer–Villiger oxidation of cycloketones using hydrogen peroxide as an oxidant. Catalysts, 13(1). https://doi.org/10.3390/catal13010021

Ma, Q. (2022). Removal of formaldehyde from aqueous solution by hydrogen peroxide. Journal of Water Chemistry and Technology, 44(4). https://doi.org/10.3103/S1063455X22040099

Ma, Q. (2021). Enhancing propene selectivity in methanol and/or butene conversion by regulating channel systems over ZSM-5/ZSM-48 composite zeolites. Microporous and Mesoporous Materials, 310. https://doi.org/10.1016/j.micromeso.2020.110803

Ma, Q. (2015). Baeyer–Villiger oxidation of cyclic ketones with hydrogen peroxide catalyzed by silica–VTMO–OSO₃H. Journal of Porous Materials, 22(5). https://doi.org/10.1007/s10934-015-9918-8

Ma, Q. (2015). Silica/A153-SO₃H: An efficient catalyst for the Baeyer–Villiger oxidation of cyclic ketones with hydrogen peroxide. Comptes Rendus Chimie, 18(4). https://doi.org/10.1016/j.crci.2014.09.002

Ma, Q. (2015). Sn-bentonite-induced Baeyer–Villiger oxidation of 2-heptylcyclopentanone to δ-dodecalactone with aqueous hydrogen peroxide. Research on Chemical Intermediates, 41(5). https://doi.org/10.1007/s11164-013-1342-6

Ashish Gome | Chemical Engineering | Best Academic Researcher Award | 13632

Published on by Research Awards

Dr. Ashish Gome | Chemical Engineering | Best Academic Researcher Award 

Prashanti Group of Institutes |  India 

Dr. Ashish Gome, Associate Professor and Dean (Academics & Administration) at Prashanti Group of Institutes, Ujjain (M.P.), has over 16 years of rich academic and professional experience spanning roles as Head of Department, Dean of External Affairs, and Dean of Academics & Administration. He brings more than six years of industrial experience as an Environmental Consultant, guiding multiple UG and PG student projects. His research focuses on chemical engineering, wastewater treatment, and advanced oxidation processes, particularly the treatment of real pharmaceutical industry wastewater. Dr. Gome has published impactful research in indexed journals, including Springer’s International Journal of Environmental Science and Technology (IJEST), ISCA journals, International Journal of Advances in Research (IJAR), and Pollution Research. His work is highly cited, providing a strong contribution to the understanding of industrial wastewater treatment with practical relevance. According to citation databases, his publications have achieved Substantial citations, and his h-index reflects his growing influence in the field. He serves as an editorial member for the International Journal of Advances in Engineering & Scientific Research. He is a lifetime member of the International Society for Research & Development, highlighting his active engagement in professional communities. Dr. Gome’s research uniquely involves the careful collection and treatment of real wastewater samples from pharmaceutical industries, analyzed under stringent conditions at the MP Pollution Control Board Regional Office. This ensures authenticity and practical applicability of his findings. His studies demonstrate significant potential for pollution load reduction and sustainable industrial practices. While his research collaborations and patents are currently limited, his publications and editorial contributions illustrate a consistent commitment to advancing knowledge. His consultancy experience enriches his academic insight, connecting theoretical work with industrial practice. Dr. Gome’s work has been widely recognized for rigor, precision, and real-world relevance, making him a strong candidate for awards in environmental engineering and chemical process innovation. His mentorship of students ensures knowledge transfer and the cultivation of future researchers. His research outputs align with global sustainability goals and demonstrate notable societal impact. The combination of publications, citations, and h-index underscores his research credibility and thought leadership. He continues to innovate within advanced oxidation processes and wastewater treatment technologies. The practical implications of his studies extend to environmental management and policy implementation.

Profile: Orcid

 

Featured Publications

“Removal of persistent chemical oxygen demand from pharmaceutical wastewater by ozonation at different pH”.

“Simulation study of phenol degradation by Fenton process using ASPEN-Plus”.

“Chemical kinetics of ozonation and other processes used for the treatment of wastewater containing pharmaceuticals: A review”.

“Biodegradability Assessment of Pharmaceutical Wastewater Treated by Ozone”.