Huiqiang Yang | Materials Engineering | Best Researcher Award

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Mr. Huiqiang Yang | Materials Engineering | Best Researcher Award

Ecole Polytechnique de Montreal, Canada

Huiqiang Yang is an accomplished materials engineer with a robust background in renewable energy systems, molten salt thermophysics, and advanced energy technologies. With more than a decade of experience spanning both academia and industry, he has become a specialist in modeling and optimizing energy systems, particularly those utilizing molten salts for thermal energy storage and concentrated solar power (CSP). Currently a Ph.D. candidate in Materials Engineering at École Polytechnique de Montréal, he is contributing to cutting-edge research in thermal conductivity modeling of complex salt mixtures under the supervision of experts at the Centre de Recherche en Calcul Thermochimique (CRCT), known for the development of FACTSAGE. Huiqiang has authored several impactful publications on predictive modeling of molten salt thermophysical properties in high-impact journals such as Solar Energy Materials and Solar Cells and Materials Today Energy. His diverse experiences include leading large-scale renewable energy projects as a senior project manager and developing international business strategies for green energy solutions. Fluent in Mandarin, French, and English, he seamlessly bridges technical expertise and cross-cultural collaboration. Huiqiang’s professional trajectory reflects a rare integration of scientific rigor, engineering application, and strategic foresight, making him a valuable asset to any advanced energy research and innovation endeavor.

Professional Profile

Education

Huiqiang Yang has cultivated a deep foundation in materials and energy engineering through an international academic journey. He is currently in the fourth year of his Ph.D. in Materials Engineering at École Polytechnique de Montréal, Canada, where he focuses on the thermophysical modeling of molten salts for advanced energy applications. His doctoral research, conducted at the renowned CRCT laboratory—home to the FACTSAGE thermochemical software—integrates modified kinetic theory and quasi-chemical models to predict thermal conductivity in multicomponent molten salt systems, particularly those with short-range ordering. His scholarly contributions are evidenced by first-author publications in top-tier journals including Solar Energy, Materials Today Energy, and Solar Energy Materials and Solar Cells. Prior to this, Huiqiang obtained a Master’s degree in Energy Engineering in 2017 with a concentration in renewable energy. His academic roots trace back to the University of Perpignan in France, where he earned a Master’s in Solar Energy and a Bachelor’s degree in Energy and Materials between 2008 and 2012. His educational background is marked by a consistent focus on solar and thermal energy technologies, underlining his commitment to sustainable energy systems and materials innovation.

Professional Experience

Huiqiang Yang brings extensive industrial experience in renewable energy systems, particularly in molten salt thermal storage and power tower technologies. From 2013 to 2020, he worked as a Research Engineer and Senior Project Manager at Shouhang High-Tech Energy Co., Ltd. in Beijing, China. He led the design and numerical modeling of two landmark CSP projects: a 10MW pilot-scale molten salt tower with 15-hour thermal storage, and a 100MW commercial-scale facility with 11-hour (1100MWh) NaNO₃-KNO₃-based storage. His responsibilities included thermal and process modeling, material selection, equipment specification, system dimensioning, and on-site supervision during construction and commissioning. His engineering reports and P&IDs were critical for project execution. Between 2015 and 2017, he also served as a Project Manager for Shouhang European S.L. in Madrid, Spain. There, he developed European market strategies, supported engineering and procurement tasks, and oversaw project execution under tight time and budget constraints. His dual role in technical leadership and business development reflects his interdisciplinary capabilities and global perspective. Huiqiang’s experience positions him at the nexus of innovation, execution, and international collaboration in the renewable energy sector.

Research Interest

Huiqiang Yang’s research interests lie at the intersection of materials science, thermochemistry, and renewable energy engineering, with a specific focus on molten salts for high-temperature thermal applications. His current Ph.D. work explores predictive models for thermal conductivity in multicomponent molten salt mixtures—materials vital for thermal energy storage in concentrated solar power (CSP) systems and nuclear reactors. He applies advanced thermodynamic frameworks such as the Modified Quasi-chemical Model in the Quadruplet Approximation, enabling accurate modeling of short-range interactions in reciprocal salt systems. Beyond thermal conductivity, his research delves into energy-material interaction mechanisms, phase equilibria, and the integration of molten salt systems into next-generation power infrastructures. He is particularly interested in how data-driven simulations and computational thermochemistry can enhance the design and efficiency of renewable energy systems. With previous hands-on experience in CSP project execution and thermal system design, Huiqiang’s research is grounded in practical relevance and industrial scalability. His overarching aim is to develop reliable and efficient energy materials and processes that support global energy transition goals. Through interdisciplinary collaboration and scientific rigor, he seeks to bridge fundamental research and real-world energy challenges.

Research Skills

Huiqiang Yang possesses a comprehensive set of research skills that span theoretical modeling, experimental design, computational simulation, and technical reporting. He is proficient in thermodynamic and kinetic modeling of molten salt systems, particularly using the FACTSAGE software platform, for which he is actively contributing at the CRCT lab. His skill set includes developing and implementing advanced models such as the Modified Quasi-chemical Model and the kinetic theory of thermal conductivity, enabling accurate predictions of thermophysical properties in multicomponent systems. He is well-versed in numerical tools like MATLAB, Python, and COMSOL Multiphysics for process modeling and simulation. In addition, Huiqiang has deep knowledge in phase diagram analysis, energy balance calculations, and the design of thermal systems, thanks to his years of industrial experience. He is adept at preparing technical documentation, including process flow diagrams (PFDs), piping and instrumentation diagrams (P&IDs), and engineering reports. His strong project management skills complement his technical expertise, allowing him to coordinate interdisciplinary teams and deliver on complex research and industrial objectives. Huiqiang also has experience presenting at conferences and publishing in high-impact journals, underscoring his capability in scientific communication and dissemination.

Awards and Honors

While specific awards are not detailed in the provided data, Huiqiang Yang’s profile reflects substantial recognition in both academic and professional domains. His selection into the prestigious Ph.D. program at École Polytechnique de Montréal, with research conducted at the globally recognized CRCT lab (a FACTSAGE developer), underscores his academic merit. The publication of multiple first-author articles in leading journals such as Solar Energy, Solar Energy Materials and Solar Cells, and Materials Today Energy serves as an acknowledgment of the high impact and originality of his research. In industry, Huiqiang rose to the position of Senior Project Manager at Shouhang High-Tech Energy Co., Ltd., where he led the development of China’s commercial-scale CSP facilities—projects considered pioneering in molten salt technology. His transition from technical roles in China to project leadership in Spain illustrates his international credibility and leadership capacity. Moreover, his multilingual abilities and capacity to work across continents in multicultural environments are professional strengths often valued in award evaluations. Collectively, these achievements point to a professional career marked by excellence, innovation, and international impact in the renewable energy field.

Conclusion

Huiqiang Yang exemplifies the ideal fusion of technical mastery, academic innovation, and real-world engineering expertise in the domain of advanced energy systems. With an educational foundation grounded in solar and materials engineering, and hands-on experience managing large-scale molten salt thermal energy projects, he brings a unique perspective to both research and implementation. His doctoral research at École Polytechnique de Montréal is pushing the frontiers of thermal conductivity modeling for multicomponent molten salt systems—critical to the future of CSP and next-generation nuclear technologies. Huiqiang’s ability to bridge theoretical modeling and practical applications is a rare and valuable asset. His publications in reputed journals and leadership roles in international energy projects demonstrate both depth and breadth of expertise. Fluent in three languages and experienced across China, Europe, and North America, he thrives in interdisciplinary, multicultural environments. Going forward, Huiqiang aspires to contribute to the development of sustainable energy infrastructures through materials innovation and system-level integration. His trajectory reflects not only technical competence but also vision, adaptability, and a commitment to solving global energy challenges. He stands out as a promising leader in the field of sustainable energy and advanced materials science.

Publications Top Notes

Title: Extending the kinetic theory‑based thermal conductivity model to reciprocal molten salt mixtures with short‑range ordering via the Modified Quasi‑chemical Model in the Quadruplet Approximation

Authors: Huiqiang Yang, Anh Thu Phan, Aimen E. Gheribi, Patrice Chartrand
Year: 2025

Japheth Obiko | Engineering Achievements | Best Researcher Award

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Dr. Japheth Obiko | Engineering Achievements | Best Researcher Award

Lecturer at Tshwane University of Technology, South Africa

Dr. Japheth Oirere Obiko is a dynamic and innovative researcher and academic specializing in mechanical and materials engineering. With a robust academic background and diverse research interests, Dr. Obiko is making significant contributions to advanced manufacturing and materials science. He currently holds dual roles as a Lecturer at the Department of Mining, Materials and Petroleum Engineering at Jomo Kenyatta University of Agriculture and Technology (JKUAT) in Kenya, and as a Postdoctoral Fellow at the Tshwane University of Technology in South Africa. His multidisciplinary research integrates cutting-edge methods in metal forming, welding metallurgy, and additive manufacturing, with a strong foundation in numerical simulation and machine learning. Dr. Obiko has authored 37 journal publications and 3 book chapters, contributing extensively to the scientific community. With editorial roles and collaborations with top-tier institutions like the University of the Witwatersrand, he demonstrates a commitment to both academic rigor and industrial applicability. His citation index reflects growing global recognition, and his mentorship of postgraduate students underscores his leadership in academic development. As a registered graduate engineer with the Engineers Board of Kenya, Dr. Obiko bridges theoretical research with practical engineering application, making him a strong contender for the Best Researcher Award.

Professional Profile

Education

Dr. Japheth Oirere Obiko’s educational journey is marked by academic excellence and specialization in engineering sciences. He obtained his Doctor of Philosophy (Ph.D.) in Chemical and Metallurgical Engineering from the prestigious University of the Witwatersrand in Johannesburg, South Africa in 2021. This rigorous doctoral program provided him with advanced competencies in material science, welding metallurgy, and computational modeling. Prior to this, he earned both his Master of Science and Bachelor of Science degrees in Mechanical Engineering from Jomo Kenyatta University of Agriculture and Technology (JKUAT), Kenya in 2015 and 2012, respectively. These formative academic stages laid a strong technical foundation in thermal systems, mechanical design, and manufacturing processes. Dr. Obiko’s educational progression illustrates a steady and deliberate move toward specialization in the emerging frontiers of materials engineering. As a registered graduate engineer with the Engineers Board of Kenya, he has translated this academic knowledge into recognized professional credentials. His pursuit of higher education not only reflects intellectual curiosity but also a determination to contribute meaningful innovations in applied engineering. Through continuous learning and scholarly inquiry, Dr. Obiko exemplifies the modern researcher—deeply informed, technically proficient, and driven by interdisciplinary engagement.

Professional Experience

Dr. Obiko has amassed a wealth of professional experience that combines academia, research, and industry consultancy. He is currently a Lecturer at Jomo Kenyatta University of Agriculture and Technology in Kenya, where he teaches and mentors students in mining, materials, and petroleum engineering. In addition to his teaching role, he serves as a Postdoctoral Fellow at Tshwane University of Technology in South Africa, engaging in advanced research in metal forming and additive manufacturing. Over the years, he has managed and participated in multiple research projects, with five significant studies either completed or ongoing. His experience includes one consultancy project that highlights his ability to translate theoretical research into practical industrial applications. Dr. Obiko’s professional footprint extends beyond teaching; it includes supervising postgraduate students, coordinating research collaborations with institutions like the University of the Witwatersrand, and contributing as a guest editor for a special issue on Smart Manufacturing in the journal Applied Sciences. His involvement in both academic and industrial environments enhances his capacity to bridge knowledge gaps and implement technological solutions. His contributions are further solidified by his authorship of numerous peer-reviewed papers and chapters, confirming his status as a respected academic and thought leader in engineering.

Research Interest

Dr. Japheth Oirere Obiko’s research interests lie at the intersection of materials engineering, computational modeling, and advanced manufacturing. He is deeply invested in understanding and enhancing processes like metal forming and welding metallurgy, both critical for industries ranging from automotive to aerospace. A key area of focus is Wire-Arc Additive Manufacturing (WAAM), where he explores novel techniques to optimize material properties and reduce production defects. His work also extends into numerical simulation, particularly through the Finite Element Method (FEM), enabling the prediction and control of complex material behaviors under various processing conditions. Additionally, Dr. Obiko is venturing into the integration of machine learning—especially Artificial Neural Networks—to improve material design and process automation. This interdisciplinary approach allows for more accurate modeling, real-time monitoring, and data-driven decision-making. His published work reflects a strong commitment to research translation, with applications that benefit both academia and industry. His interests not only align with global priorities in smart manufacturing and sustainable development but also showcase a futuristic vision of engineering that is responsive to emerging technologies. Through collaboration and innovation, Dr. Obiko continues to expand the boundaries of knowledge in applied materials science.

Research Skills

Dr. Obiko is equipped with a diverse and sophisticated array of research skills that enable him to undertake complex engineering investigations and produce impactful results. He is proficient in metal forming analysis and experimental mechanics, essential for optimizing deformation processes and improving material performance. His expertise in welding metallurgy includes the study of microstructural evolution and mechanical properties of welded joints, with practical relevance to industrial fabrication. He is highly skilled in Wire-Arc Additive Manufacturing (WAAM), a cutting-edge technology that he employs to explore new material structures and component efficiencies. Dr. Obiko’s computational skills are particularly advanced; he utilizes Finite Element Method (FEM) tools such as ANSYS and DEFORM for simulations involving thermal, mechanical, and structural analysis. Additionally, he is adept in data-driven modeling using machine learning tools, especially Artificial Neural Networks (ANN), which he incorporates to enhance predictive accuracy and optimization. These computational methods are complemented by his hands-on laboratory expertise in alloy design, microstructure characterization, and mechanical testing. His ability to blend experimental and numerical techniques provides a comprehensive framework for scientific inquiry. Dr. Obiko’s skill set is robust, interdisciplinary, and well-aligned with the demands of modern research in materials and manufacturing.

Awards and Honors

Dr. Japheth Obiko’s achievements in engineering research have earned him recognition within both academic and professional circles. His appointment as a Guest Editor for the Applied Sciences journal’s Special Issue on “Advanced Metal Forming and Smart Manufacturing Processes” is a testament to his expertise and leadership in the field. This role not only highlights his editorial acumen but also his recognition as a subject-matter expert globally. His doctoral and postdoctoral affiliations with leading institutions such as the University of the Witwatersrand and Tshwane University of Technology further reflect his academic merit. While he has not yet been formally awarded national or international medals, the depth of his contributions—spanning over 37 peer-reviewed journal publications and three scholarly book chapters—showcases a sustained and high-impact research trajectory. His citation index in Scopus and multiple collaborative efforts with global institutions provide further evidence of his growing influence. As a registered member of the Engineers Board of Kenya and an active contributor to industrial consultancy projects, Dr. Obiko has demonstrated both academic excellence and practical engagement. His dedication to research, innovation, and mentorship positions him as a strong candidate for the Best Researcher Award.

Conclusion

In conclusion, Dr. Japheth Oirere Obiko exemplifies the qualities of a forward-thinking researcher, educator, and professional engineer. His academic journey from Jomo Kenyatta University of Agriculture and Technology to internationally recognized institutions such as the University of the Witwatersrand has laid a strong foundation for his career in advanced manufacturing and materials science. His prolific research output, spanning 37 journal publications and several collaborative projects, reflects both depth and breadth in subject matter expertise. Moreover, his roles as a lecturer, postdoctoral researcher, and guest editor demonstrate a commitment to academic excellence, interdisciplinary collaboration, and mentorship. Dr. Obiko’s integration of simulation techniques, welding technologies, and machine learning into engineering research addresses real-world challenges and promotes innovation. His contributions are timely and relevant, aligning with global goals for sustainable, smart manufacturing. Although still early in his professional trajectory, his influence is rapidly growing, as evidenced by his scholarly citations and editorial invitations. By maintaining strong industry ties and fostering future engineers, he continues to impact both theory and practice. Dr. Obiko stands out as a highly deserving nominee for the Best Researcher Award, representing the next generation of African scholars leading transformative change in science and technology.

Publications Top Notes

1. Title: Advancing the hydrogen production economy: A comprehensive review of technologies, sustainability, and future prospects
Authors: SO Jeje, T Marazani, JO Obiko, MB Shongwe
Year: 2024
Citations: 95

2. Title: Finite element simulation of X20CrMoV121 steel billet forging process using the Deform 3D software
Authors: JO Obiko, FM Mwema, MO Bodunrin
Year: 2019
Citations: 50

3. Title: An overview of conventional and non-conventional techniques for machining of titanium alloys
Authors: SR Oke, GS Ogunwande, M Onifade, E Aikulola, ED Adewale, …
Year: 2020
Citations: 46

4. Title: Forging optimisation process using numerical simulation and Taguchi method
Authors: JO Obiko, FM Mwema, H Shangwira
Year: 2020
Citations: 23

5. Title: Validation and optimization of cutting parameters for Ti-6Al-4V turning operation using DEFORM 3D simulations and Taguchi method
Authors: JO Obiko, FM Mwema, MO Bodunrin
Year: 2021
Citations: 22

6. Title: A multi-response optimization of the multi-directional forging process for aluminium 7075 alloy using grey-based Taguchi method
Authors: C Obara, FM Mwema, JN Keraita, H Shagwira, JO Obiko
Year: 2021
Citations: 19

7. Title: Friction correction of flow stress-strain curve in the upsetting process
Author: J Obiko
Year: 2021
Citations: 16

8. Title: Effect of punch force on the upsetting deformation process using three-dimensional finite element analysis
Authors: FM Mwema, JO Obiko, ET Akinlabi, SA Akinlabi, OS Fatoba
Year: 2019
Citations: 14

9. Title: On the uniaxial compression testing of metallic alloys at high strain rates: an assessment of DEFORM-3D simulation
Authors: M Bodunrin, J Obiko, D Klenam
Year: 2023
Citations: 13

10. Title: Strain rate-strain/stress relationship during isothermal forging: a deform-3D FEM
Authors: J Obiko, F Mwema, ET Akinlabi
Year: 2020
Citations: 13

Salah Almudhhi | Petroleum Engineering | Best Researcher Award

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Prof. Salah Almudhhi | Petroleum Engineering | Best Researcher Award

Professor at Kuwait University, Kuwait

Dr. Salah M. Almudhhi is a distinguished academic and expert in petroleum engineering, renowned for his multidisciplinary approach that combines traditional petroleum technologies with cutting-edge innovations like nanotechnology and machine learning. With a professional journey spanning over three decades, Dr. Almudhhi currently serves as an Assistant Professor at Kuwait University, where he has played integral roles in both academic and administrative capacities. His academic credentials are rooted in petroleum engineering, having earned his B.S. from Kuwait University and his M.S. and Ph.D. from the Colorado School of Mines in the USA. Dr. Almudhhi has held leadership roles in national environmental bodies, including serving as Director General of the Environment Public Authority in Kuwait. He has published extensively in high-impact journals, with key contributions in enhanced oil recovery, wettability measurements, and rock-fluid characterization. Dr. Almudhhi has supervised numerous graduate research projects and has actively participated in national and international committees related to energy and environmental policy. Recognized with multiple honors, including the “Environment Person of the Year in Asia 2012,” he continues to bridge academia, industry, and policy through his expertise and dedication. His work is distinguished by its practical impact on sustainable energy production and environmental stewardship in the petroleum sector.

Professional Profile

Education

Dr. Salah M. Almudhhi’s educational journey reflects a robust and focused progression in the field of petroleum engineering. He began his academic pursuits at Kuwait University, where he earned a Bachelor of Science degree in Petroleum Engineering in 1994. Building upon this foundation, he pursued advanced studies at the prestigious Colorado School of Mines in the United States, where he obtained both his Master of Science in 1998 and his Doctor of Philosophy in 2003. His M.S. thesis, titled “The ‘Spinning Disk’ Approach to Capillary Pressure Measurement with a Centrifuge Experiment,” demonstrated his early focus on experimental techniques in reservoir engineering. For his Ph.D. dissertation, “Experimental Evaluation of the Petrophysical Algorithm in an Integrated Flow Model,” Dr. Almudhhi explored the integration of petrophysical data into dynamic reservoir simulations, establishing his specialization in enhanced recovery modeling. His academic training provided him with a deep understanding of both theoretical and applied aspects of petroleum systems. This solid educational background laid the groundwork for his innovative research and teaching in reservoir characterization, rock mechanics, and environmental impact assessments in the oil and gas industry. His education has continuously informed his interdisciplinary approach to engineering challenges and policy leadership.

Professional Experience

Dr. Salah M. Almudhhi brings a wealth of professional experience that bridges academia, industry, and environmental governance. He began his academic career as a Teaching Assistant at the Colorado School of Mines from 2000 to 2002. Following his Ph.D., he joined Kuwait University as an Assistant Professor in 2003 and resumed this role after a leadership stint, continuing from 2014 to the present. He served as Acting Chairman of the Petroleum Department in 2004 and played a key role in curriculum development and faculty advancement. From 2009 to 2014, Dr. Almudhhi was appointed Director General of Kuwait’s Environment Public Authority, where he simultaneously chaired multiple national environmental and energy committees. His portfolio included roles such as Executive Secretary of the Supreme Council for the Environment and State Representative to numerous UN and GCC environmental programs. He has also held prominent advisory positions in Kuwait’s Ministry of Public Works and Ministry of Education. Within the university, he has served on various departmental, college, and university-level committees, emphasizing research development, international cooperation, and strategic planning. Dr. Almudhhi’s blend of technical expertise, academic rigor, and environmental advocacy positions him as a highly influential figure in both scientific and governmental domains.

Research Interest

Dr. Salah M. Almudhhi’s research interests focus on the interplay between rock-fluid properties, enhanced oil recovery, and the integration of emerging technologies in petroleum engineering. His foundational work in rock and fluid characterization laid the basis for deeper exploration into wettability, a key factor influencing reservoir performance. His investigations into wettability measurements—particularly in carbonate and shale reservoirs—have enhanced understanding of capillary pressure behavior and contact angle variability. Dr. Almudhhi has also directed research toward the application of nanotechnology in improving oil recovery, emphasizing the role of nanoparticle-engineered fluids in tight formations. His current research delves into machine learning applications for modeling heavy oil viscosity and rock mechanics, aiming to bridge data science with traditional reservoir engineering. Through collaborative graduate research projects, he supervises work on fluid dynamics, permeability modeling, and tensile strength in relation to brine salinity. Additionally, Dr. Almudhhi maintains an active interest in environmental monitoring and its implications for upstream petroleum operations. His research is geared toward solutions that improve reservoir performance while maintaining ecological balance. With an integrative approach that spans experimental, computational, and environmental disciplines, Dr. Almudhhi continues to contribute significantly to the evolution of petroleum science and sustainability.

Research Skills

Dr. Salah M. Almudhhi possesses a comprehensive array of research skills that underscore his interdisciplinary and application-focused approach to petroleum engineering. His core technical strengths lie in rock and fluid characterization, including advanced wettability analysis, capillary pressure evaluation, and relative permeability measurements. He has significant experience with both conventional laboratory techniques and modern analytical methods such as nuclear magnetic resonance (NMR) and spinning disk centrifuge experiments. Dr. Almudhhi has developed proficiency in modeling and simulation, particularly in the use of integrated flow models to interpret petrophysical data. His recent work involves leveraging machine learning tools to predict oil viscosity and compressive strength in reservoir rocks, showcasing his adaptability in digital technologies. He also has expertise in environmental assessment methodologies, having designed impact studies and coordinated national reports under frameworks like the UNFCCC. Dr. Almudhhi’s ability to bridge experimental research with computational analytics has been reflected in over 17 peer-reviewed publications. He actively applies his research skills in supervising student projects, grant acquisition, and curriculum development. His scientific rigor, coupled with policy-driven applications, allows him to contribute meaningfully to both academic and environmental solutions in the petroleum and energy sectors.

Awards and Honors

Dr. Salah M. Almudhhi has received multiple awards and recognitions for his exceptional contributions to petroleum engineering and environmental policy. Among his most prestigious accolades is the “Environment Person of the Year in Asia” award, conferred in 2012 in Dubai, UAE. This award acknowledged his pioneering work in bridging petroleum science with environmental stewardship during his tenure as Director General of the Environment Public Authority in Kuwait. He was also the recipient of the “Award of Recognition in Environment” from the Kuwait Oil Company in 2010, reflecting his national impact on sustainable practices in the energy sector. Additionally, Dr. Almudhhi was honored with the GCC Environmental Achievement Award in Oman in 2011, which recognized his efforts in regional environmental collaboration and policy development. His involvement in numerous high-level environmental committees, both regionally and internationally, underscores the respect he commands as a scientific advisor and public policy expert. His memberships in professional societies, such as the Society of Petroleum Engineers and the Kuwait Society of Engineers, further affirm his standing in the global engineering community. These honors collectively reflect a career committed to excellence in research, teaching, and service to society.

Conclusion

In conclusion, Dr. Salah M. Almudhhi stands as a highly accomplished and visionary figure in the realm of petroleum engineering, whose work seamlessly integrates academic excellence, research innovation, and public policy leadership. With advanced degrees from the Colorado School of Mines and a longstanding commitment to Kuwait University, he has shaped a generation of engineers through his teaching, mentorship, and curricular contributions. His diverse research portfolio—ranging from wettability and nanofluid applications to machine learning modeling—demonstrates a proactive engagement with the evolving challenges of energy production. His leadership roles in environmental governance, including his service as Director General of the Environment Public Authority, reflect his dedication to sustainability and international collaboration. A recipient of multiple national and international awards, Dr. Almudhhi continues to influence both academia and public institutions through his strategic insight and interdisciplinary expertise. His legacy is not only marked by his scholarly publications and student mentorship but also by his commitment to integrating technological advancement with environmental responsibility. As a leader, educator, and researcher, Dr. Almudhhi exemplifies the transformative power of science in addressing real-world challenges in the oil and energy sectors.

Publications Top Notes

  1. Application of Machine Learning for Modeling Heavy Oil Viscosity
    Authors: Salah Almudhhi, Haitham M.S. Lababidi, Ali A. Garrouch
    Year: 2025

  2. Are Natural Fractures in Sandstone Reservoir: Water Wet – Mixed Wet – Or Oil Wet?
    Authors: Salah Almudhhi, Laila Abdullah, Waleed Al-Bazzaz, Saleh Alsayegh, Hussien Alajaj, Ralph Flori
    Year: 2022

  3. An Unconventional Approach in Investigating Wettability Contact Angle Measurement in Shale Resources
    Author: Salah Almudhhi
    Year: 2021

  4. Predicting the Flow Zone Indicator of Carbonate Reservoirs Using NMR Echo Transforms and Routine Open-Hole Log Measurements
    Authors: Salah Almudhhi, M. Al-Dousari, A. Garrouch
    Year: 2021

  5. Investigating Wettability Contact Angle Measurement in Kuwaiti Heavy Oil Reservoir and Modeling Using 2D Imaging Technologies
    Authors: Waleed Albazzaz, Salah Almudhhi, Mohammed Alostath
    Year: 2019

  6. Recovery of Crude from OVL in Joint Operations, Wafra, Kuwait
    Author: Salah M. Almudhhi
    Year: 2016

  7. Histopathological Survey of Potential Biomarkers for the Assessment of Contaminant Related Biological Effects in Species of Fish and Shellfish Collected from Kuwait Bay, Arabian Gulf
    Authors: S. Masoud, Salah Almudhhi, M. Alenezi
    Year: 2014

  8. Investigating Rock-Face Boundary Effects on Capillary Pressure and Relative Permeability Measurements
    Authors: O. A. Alomair, Salah M. Almudhhi, M. M. Aldousari
    Year: 2011

  9. An Experimental Investigation of the Impact of Diffusion Osmosis and Chemical Osmosis on the Stability of Shales
    Authors: T. Al-Bazali, Salah Almudhhi, M. Chenevert
    Year: 2011

  10. Averaging Effect on Elastic Wave Velocity in an Integrated Flow Model
    Authors: S. M. Almudhhi, O. Alomair
    Year: 2009

  11. Experimental Evaluation of the Petrophysical Algorithm in an Integrated Flow Model
    Authors: S. M. Almudhhi, J. R. Fanchi
    Year: 2009

  12. Experimental Presentation of an Integrated Flow Model
    Author: S. M. Almudhhi
    Year: 2007