Mr. Arif Aziz | Thermodynamics of Materials | Best Researcher Award

Mr. Arif Aziz is a PhD student at Harbin Engineering University specializing in mechanical and power engineering with a focus on turbomachinery. He holds a Bachelor’s in Mechanical Engineering and a Master’s in Power Engineering and Engineering Thermophysics. His work explores advanced two-phase flow dynamics and working fluid mixtures in closed Brayton cycle compressors, with contributions to conference proceedings and peer-reviewed journals. His research is directed toward enhancing compressor performance and improving power cycle efficiency for applications in next-generation energy systems.

Mr. Arif Aziz | Harbin Engineering University | China

Profile

SCOPUS

Education

Mr. Aziz completed his Bachelor’s degree in Mechanical Engineering, followed by a Master’s degree in Power Engineering and Engineering Thermophysics, where he focused on aerodynamic analysis and optimization of compressors. Currently, he is pursuing his PhD at Harbin Engineering University in the same field, concentrating on developing optimized compressor designs for binary gas mixtures like helium-xenon and helium-nitrogen. His educational journey reflects a progressive specialization in fluid mechanics and turbomachinery design, providing a solid academic foundation for high-level research.

Mr. Aziz has completed a research project on the optimization of an axial flow compressor and is presently engaged in a project investigating the thermodynamic and aerodynamic behavior of binary gas mixtures in closed Brayton cycle compressors. His research aims to enhance efficiency, stability, and power density in advanced energy systems. With publications in international journals such as Case Studies in Thermal Engineering and Journal of Hydrogen Energy, he contributes valuable insights into energy-efficient turbomachinery systems.

Research Focus

Mr. Aziz’s primary research focus lies in understanding and improving two-phase flow dynamics and working fluid interactions in compressors for closed Brayton cycles. His studies target helium-based mixtures to optimize cooling, efficiency, and power density, which are vital for nuclear and solar-thermal power generation. By combining experimental and computational techniques, he aims to deliver novel compressor designs that address energy efficiency challenges in next-generation power systems.

Publications

Optimization of an Axial Flow Compressor Cooling: A Numerical Study on Enhanced Wet Compression Technology
Authors: Arif Aziz, Ghulam Ishaque, Naseem Ahmad, Muhammad Haris

CO2 Capture Using Mixed Amines: Experimental DFT Investigation with Focus on Improvements in Cyclic Efficiency and NO Interference
Authors: Muhammad Haris, Arif Aziz, Muhammad Sohail, Waseem Sardar

Aerodynamic Performance Investigation of an Axial Flow Compressor Under Water Ingestion
Authors: Ghulam Ishaque, Qun Zheng, Naseem Ahmad, Arif Aziz

The Influence of the Casing Grooves on the Performance of an Axial Compressor
Authors: Naseem Ahmad, Ghulam Ishaque, Arif Aziz, Qun Zheng

Adaptive Multiplexing Technique for Mobile Networks Based on SNR
Authors: Abdul Ahad Dilshad, Muhammad Irfan, Adil Malik, Arif Aziz

Conclusion

Mr. Arif Aziz is an emerging researcher with a strong academic background, focused research direction, and contributions to improving energy system performance through turbomachinery innovations. His work is impactful for future clean energy solutions and demonstrates the potential for broader applications in advanced power cycles. These qualities collectively make him a suitable and competitive candidate for the Best Researcher Award.

Dr. Jingna Liu | Thermodynamics of Materials | Best Researcher Award

Dr. Jingna Liu is an Assistant Professor at Sun Yat-sen University, with a doctoral degree in Soil Science from the University of Copenhagen. Her academic foundation bridges advanced environmental science and agricultural sustainability. After completing her Ph.D., she began her research and teaching career in China, focusing on soil fertility and agricultural waste valorization. Her professional trajectory demonstrates a commitment to improving nutrient management and promoting sustainable agriculture through interdisciplinary and applied research.

Dr. Jingna Liu | Sun Yat-Sen University | China

Profile

SCOPUS

Education

Dr. Liu earned her Ph.D. in Soil Science from a leading European institution, where she specialized in nutrient cycling and soil health. Her education integrated core aspects of environmental sustainability, microbiology, and agricultural chemistry. The combination of European academic standards and applied agricultural focus equipped her with both theoretical insight and practical skill, enabling her to address complex challenges in agricultural waste management and soil resource efficiency.

Experience

Dr. Liu has developed her academic career as an Assistant Professor at Sun Yat-sen University. She has completed and led multiple research projects related to agricultural waste recycling and soil fertility enhancement. Her experience includes both academic research and consultancy collaborations with industry stakeholders, contributing to real-world applications of her findings. With an active presence in both research and academic mentoring, she plays a significant role in advancing sustainable agricultural practices.

Contribution

Dr. Jingna Liu’s research has made pivotal contributions to sustainable agriculture by optimizing the thermal drying process of solid digestate. Her work uncovered the fundamental mechanisms of nitrogen transformation and demonstrated that acidification prior to drying significantly reduces ammonia (NH₃) volatilization while enhancing plant-available nitrogen. This innovation boosts the fertilizer value of dried digestate, enabling its conversion into a nutrient-rich organic fertilizer. By improving nutrient retention and reducing dependency on synthetic fertilizers, her findings support circular agriculture, waste valorization, and improved environmental stewardship.

Research Focus 

Dr. Liu’s research focuses on the recycling and utilization of agricultural solid waste, soil fertility enhancement, and nitrogen use efficiency. She investigates thermal drying and acidification processes to optimize nitrogen retention and reduce environmental emissions. Her work emphasizes the transformation of organic waste into effective fertilizers, offering solutions for improving soil health and reducing dependence on chemical inputs. Her studies provide scientific insights that support practical applications in sustainable farming systems.

Publications

Effect of Acidification on Nitrogen Transformation of Solid Digestate During Thermal Drying
Authors: Weimin Wu, Jingna Liu
Journal: Published July 2025

Acidification Prior to Drying of Digestate Solids Affects Nutrient Uptake and Fertilizer Value When Applied to Maize
Authors: Jingna Liu, Dorette Sophie Müller-Stöver, Lars Stoumann Jensen
Journal: Published September 2024

Comparison of Alum and Sulfuric Acid to Retain and Increase the Ammonium Content of Digestate Solids During Thermal Drying
Authors: Jingna Liu, Lars Stoumann Jensen, Dorette Müller-Stöver
Journal: Published June 2021

Acidified Animal Manure Products Combined with a Nitrification Inhibitor Can Serve as a Starter Fertilizer for Maize
Authors: Iria Regueiro, Peter Siebert, Jingna Liu, Lars Stoumann Jensen
Journal: Published December 2020

Methane Emission and Soil Microbial Communities in Early Rice Paddy as Influenced by Urea-N Fertilization
Authors: Jingna Liu, Huadong Zang, Heshui Xu, Zhaohai Zeng
Journal: Published December 2019

Increased Retention of Available Nitrogen During Thermal Drying of Solids of Digested Sewage Sludge and Manure by Acid and Zeolite Addition
Authors: Jingna Liu, Andreas de Neergaard, Lars Stoumann Jensen
Journal: Published September 2019

Conclusion

Dr. Jingna Liu is a promising and impactful researcher contributing to the advancement of sustainable agriculture through innovative research on nutrient recycling and soil fertility. Her scientific insights into nitrogen retention and emissions reduction place her as a suitable candidate for the Best Researcher Award. With expanded global engagement and broader application of her findings, she is well-positioned to become a leading figure in environmental soil science and sustainable waste management.

Dr. Swami Nath Maurya | Thermodynamics of Materials | Best Researcher Award

Dr. Swami Nath Maurya is a Postdoctoral Researcher at the National Chin-Yi University of Technology (NCUT) in Taiwan, specializing in thermal management and precision manufacturing. He holds a Ph.D. in Precision Manufacturing, a Master’s in Green Energy Technology, and a B.Tech. in Instrumentation and Control Engineering. With 13 SCIE-indexed journal publications and an h-index of 5, Dr. Maurya merges experimental research with AI modeling to optimize energy and material efficiency. His multidisciplinary expertise spans semiconductors, machine tools, and advanced thermal systems.

Dr. Swami Nath Maurya | National Chin-Yi University of Technology | Taiwan

Profile

SCOPUS

ORCID

GOOGLESCHOLAR

Education 

Dr. Maurya’s academic journey is marked by a solid foundation in engineering and sustainability. He earned his B.Tech. in Instrumentation and Control Engineering, followed by a Master’s in Green Energy Technology, which underpins his commitment to sustainable development. He then pursued a Ph.D. in Precision Manufacturing, focusing on intelligent process optimization. This academic progression reflects his strong theoretical understanding and applied engineering acumen in the areas of energy efficiency, thermal modeling, and manufacturing systems.

Experience

Dr. Maurya has worked extensively as a postdoctoral researcher, contributing to thermal management in machine tool systems, semiconductor crystal growth (Czochralski process), and graphene-enhanced membranes. He has authored studies on AI-driven optimization, multiobjective cooling, and microfluidic heat sink design. His work is known for solving practical engineering problems with academic rigor, and he collaborates across Taiwan and India. Despite having no current patents or editorial roles, his contributions stand out for their technical depth and industrial relevance.

Contributions 

Dr. Swami Nath Maurya has made significant contributions to thermal management, semiconductor process optimization, and sustainable material engineering. His research includes the Czochralski crystal growth process, graphene-based membranes, and hybrid cooling systems for enhanced energy efficiency and system reliability. His 13 SCIE-indexed publications (h-index: 5) reflect innovation at the intersection of AI, thermal modeling, and advanced manufacturing. From machine tool spindle cooling to microfluidic heat sinks, his work promotes intelligent, eco-conscious engineering practices for future-ready industries.

Research Focus 

Dr. Maurya’s research centers on thermal deformation modeling, energy-efficient systems, and AI-enhanced process optimization. His work targets complex engineering challenges in machine tools, semiconductor manufacturing, and sustainable material processing. He employs finite element methods, Monte Carlo simulations, and neuro-fuzzy inference systems to optimize system efficiency. By bridging artificial intelligence, green energy, and manufacturing, he is contributing to next-generation, eco-conscious industrial solutions.

Publications

Performance and Economic Enhancement of a Dewaxing Casting Process Using a Heat Pump Drying System
Authors: Win-Jet Luo, Amir Reza Ansari Dezfoli, Swami Nath Maurya, Bivas Panigrahi, Pei-Tang Wang
Journal: Case Studies in Thermal Engineering (2025)

Performance Analysis of Energy Recovery Membrane Coated with Graphene Oxide
Authors: Win Jet Luo, Prateek Negi, Swami Nath Maurya, Bivas Panigrahi, Janet Syah Putra Telaumbanua
Journal: Materials Research Express (2025)

Efficient Heat Dissipation with Hybrid Composite-Based Microfluidic Heat Sinks in Flexible Electronics
Authors: Pramod Vishwakarma, Swami Nath Maurya, Win Jet Luo, Bivas Panigrahi
Journal: Journal of Micromechanics and Microengineering (2025)

Optimization of Machine Tool Spindle Cooling for Enhancement of Thermal Prediction Accuracy and Energy Efficiency
Authors: Cheng-Kai Huang, Tsung-Chia Chen, Kun-Ying Li, Yuan-Hong Tsai, Swami Nath Maurya
Journal: International Journal of Precision Engineering and Manufacturing-Green Technology (2025)

Data-Driven Approach for Optimizing the Czochralski Process and Predictive Modeling: A Finite Element and Machine Learning Analysis
Authors: Swami Nath Maurya, Amir Reza Ansari Dezfoli, Li-Shang Lin
Journal: The International Journal of Advanced Manufacturing Technology (2025)

Process Parameter Optimization in Czochralski Growth of Silicon Ingots: A Monte Carlo-Finite Element Coupled Model
Authors: Amir Reza Ansari Dezfoli, Swami Nath Maurya, Zary Adabavazeh, Yi-Jen Huang
Journal: The International Journal of Advanced Manufacturing Technology (2025)

Impact of Top Cooling on Defect Suppression in Large-Scale Silicon Ingot Manufacturing
Authors: Yi-Jen Huang, Swami Nath Maurya, Amir Reza Ansari Dezfoli
Journal: The International Journal of Advanced Manufacturing Technology (2025)