Mahasakti Mahamaya | Geotechnical Engineering | Women Researcher Award

Published on by Civil Engineering

Dr. Mahasakti Mahamaya | Geotechnical Engineering | Women Researcher Award

Associate Professor | OP Jindal University | India

Dr. Mahasakti Mahamaya is a distinguished researcher whose academic contributions span across engineering and interdisciplinary sciences, with a focus on innovative methodologies, sustainable development, and applied technologies. Her research portfolio demonstrates significant depth, addressing complex real-world challenges through analytical precision and forward-looking inquiry. Dr. Mahamaya has authored a substantial number of peer-reviewed papers in reputed international journals and conferences, contributing extensively to the advancement of knowledge in her field. Her work has attracted a remarkable level of global attention, reflected through 483 total citations and 445 citations since 2020, underscoring the continuing influence of her research. With an h-index of 10 and an i10-index of 10, Dr. Mahamaya has consistently maintained scholarly excellence and research impact across multiple domains. She has actively collaborated with experts and institutions worldwide, strengthening multidisciplinary networks and fostering the integration of academic research with industry and policy frameworks. Her studies have advanced understanding in areas such as material behavior, computational modeling, and sustainable engineering practices, while also highlighting the societal and environmental implications of technological innovation. Through mentorship, publication, and collaborative initiatives, Dr. Mahamaya has contributed to nurturing a new generation of researchers and to shaping future-oriented strategies in engineering and applied science. Her sustained academic engagement and global recognition underscore a career dedicated to impactful, ethically grounded, and socially relevant scientific inquiry, positioning her as a leading figure in her research domain.

Profile: Scopus | ORCID | Google Scholar
Featured Publications:

Suman, S., Mahamaya, M., & Das, S. K. (2016). Prediction of maximum dry density and unconfined compressive strength of cement stabilised soil using artificial intelligence techniques. International Journal of Geosynthetics and Ground Engineering, 2(2), 1–11.

Mahamaya, M., Das, S. K., Reddy, K. R., & Jain, S. (2021). Interaction of biopolymer with dispersive geomaterial and its characterization: An eco-friendly approach for erosion control. Journal of Cleaner Production, 127778.

Parhi, P. S., Garanayak, L., Mahamaya, M., & Das, S. K. (2017). Stabilization of an expansive soil using alkali activated fly ash based geopolymer. International Congress and Exhibition "Sustainable Civil Infrastructures".

Mahamaya, M., & Das, S. K. (2017). Characterization of mine overburden and fly ash as a stabilized pavement material. Particulate Science and Technology, 35(6), 660–666.

Das, S. K., Mahamaya, M., & Reddy, K. R. (2020). Coal mine overburden soft shale as a controlled low strength material. International Journal of Mining, Reclamation and Environment, 34(10), 725–747.

Changxin Huang | Geotechnical Engineering | Best Researcher Award

Published on by Civil Engineering

Dr. Changxin Huang | Geotechnical Engineering | Best Researcher Award

Doctoral student | Shandong University | China

The research fields of Dr. Changxin Huang encompass advanced studies in sustainable and intelligent civil engineering materials, focusing primarily on multifunctional and smart concretes through the integration of nanotechnology. The research explores the development of high-performance cementitious composites with self-sensing, self-healing, and durability-enhancing capabilities to address challenges in modern infrastructure systems. Emphasis is placed on the design and optimization of nano-engineered materials such as carbon-based nanomaterials, graphene, and carbon nanotubes to improve mechanical strength, electrical conductivity, and structural monitoring efficiency. Huang’s work also extends to the application of intelligent monitoring systems for civil infrastructure, utilizing embedded sensors and data-driven technologies to enable real-time structural health monitoring and predictive maintenance. Additional areas of interest include green and sustainable construction materials, energy-efficient concrete structures, and recycling of industrial by-products for eco-friendly material synthesis. The research integrates experimental testing, numerical modeling, and machine learning approaches to predict material performance and optimize formulation strategies. Huang’s contributions aim to bridge material science and structural engineering, promoting the transition toward intelligent, resilient, and low-carbon construction systems. The interdisciplinary approach combines principles from materials engineering, nanotechnology, and data analytics to enhance infrastructure performance and sustainability. Overall, the research advances the vision of next-generation civil infrastructure that is adaptive, energy-efficient, and environmentally responsible through innovative multifunctional concrete technologies and smart monitoring systems.

Profile: Scopus | ORCID
Featured Publications:

A stepwise calculation method for grouting penetration in rough rock fracture based on fracture segment division. (2025). Tunnelling and Underground Space Technology.

Jibin Sun – Geotechnical Engineering – Best Researcher Award

Published on by Civil Engineering

Jibin Sun - Geotechnical Engineering - Best Researcher Award

Research Associate | Tianjin University | China

Dr. Jibin Sun has established a strong research foundation in geotechnical and civil engineering, focusing on the stability, performance, and safety of underground and foundation structures. His work addresses critical challenges in tunneling engineering, including progressive failure mechanisms, local failure impacts on adjacent structures, and the effects of contact loss under shield tunnel inverts. Through both experimental and numerical studies, he has contributed to advancing knowledge in tunnel safety, ground-structure interaction, and pile behavior under cyclic loading in dry sand. His studies integrate innovative modeling techniques such as Eulerian finite element methods and Coupled Eulerian–Lagrangian simulations, demonstrating a balance of theoretical analysis and applied engineering solutions. Jibin Sun’s research outputs, published in high-impact journals like Tunnelling and Underground Space Technology, Acta Geotechnica, Géotechnique, and Engineering Failure Analysis, showcase his consistent focus on addressing complex geotechnical problems with practical relevance for infrastructure safety and resilience. Recognition through awards such as the Tianjin Science and Technology Progress Award and the Excellent Doctoral Dissertation Award of Tianjin University highlights the value and influence of his contributions. Supported by prestigious funding programs, his ongoing work continues to expand the frontiers of geotechnical engineering, particularly in underground construction and failure mechanism analysis, positioning him as an impactful contributor to the field. 342 Citations by 288 documents, 20 Documents, 9 h-index View.

Profile: Scopus
Featured Publications: 

  1. Experimental study of the effects of contact loss under a shield tunnel invert. (2024). Cited by 2.

  2. Coupled Eulerian-Lagrangian simulation of progressive failure in shield tunnels induced by developing contact loss. (2024). Cited by 8.

Zhiliang Wang – Geotechnical Engineering – Best Researcher Award

Published on by Civil Engineering

Prof. Zhiliang Wang | Geotechnical Engineering | Best Researcher Award

Professor | Kunming University of Science and Technology | China

Prof. Zhiliang Wang has established a strong research foundation in civil and geotechnical engineering, focusing extensively on tunnel and underground engineering, soil behavior, and numerical simulation methods. His research contributions address safety evaluation of tunnels, mitigation of hazards associated with special soils, and the development of multi-field coupling models for geotechnical applications. By integrating theoretical modeling with experimental studies, Zhiliang Wang has advanced understanding of soil stabilization mechanisms, long-term settlement issues in peat soils, and fracture propagation in rock mass. His works also highlight the application of lattice Boltzmann methods for simulating fluid flow, heat transfer, and seepage in complex soil and rock structures, bridging the gap between computational approaches and practical engineering challenges. Through projects supported by the National Natural Science Foundation of China and industry collaborations, he has contributed innovative solutions for freezing processes in soils, shield tunneling effects, and soil-structure interaction in underground construction. His publications in high-impact journals cover a wide range of topics, from sustainable approaches such as incorporating clay and manufactured sand in soil stabilization to advanced simulations of thermal and hydraulic processes in soils. Zhiliang Wang’s research outcomes not only enhance engineering safety and efficiency but also align with sustainability goals by addressing energy-efficient and environmentally friendly practices in geotechnical engineering. His active involvement in teaching courses like tunnel engineering and numerical simulation further strengthens the link between academic research and practical application, inspiring future professionals in the field. With 366 citations by 339 documents, 65 documents, and an h-index of 11, Zhiliang Wang’s scholarly impact reflects his significant role in shaping modern research and innovations in underground engineering and soil mechanics.

Profile: Scopus
Featured Publications: 

  1. Effect of random microcracks on macroscopic crack propagation in rock. (2024). Cited by 2.

  2. A numerical simulation of high-temperature rock hydraulic fracturing based on coupled thermo-mechanical peridynamics. (2024). Cited by 1.

  3. Study on the seepage and heat transfer effect of rough fractures in hot matrix considering dynamic thermophysical properties of fluid. (2024). Cited by 2.

  4. Numerical simulation of glass panel impact damage based on peridynamics. (2024). Cited by 1.