Yaling Deng - Mechanical engineering/Bio-tribology - Best Researcher Award

Jinling Institute of Technology - China

AUTHOR PROFILE

SCOPUS

YALING DENG: EXPERT IN BIOTRIBOLOGY 🔬

Yaling Deng is a prominent figure in the fields of biotribology, biomaterials, and surface engineering. She is currently a lecturer at the Jinling Institute of Technology, where her research focuses on the tribological behavior of biomaterials and surface modification techniques. Her expertise lies in developing advanced materials for medical applications, particularly in artificial joints and tissue engineering.

EDUCATIONAL BACKGROUND 🎓

Yaling earned her PhD in Materials Science and Engineering from Nanjing University of Science and Technology in 2016. Before that, she completed her undergraduate studies in physics at Dezhou University in 2010 and later pursued postdoctoral research in mechanical engineering at Nanjing Forestry University from 2017 to 2020. Her academic journey laid a strong foundation for her research in biomimetic materials and surface engineering.

CURRENT RESEARCH INTERESTS 🔍

Yaling's research centers on biomaterials, surface engineering, and biotribology, with a focus on polymer hydrogels and nanoparticles. She investigates how these materials can be used to improve the lubrication and wear resistance of artificial joints. Her work in surface coatings and modifications aims to enhance the mechanical performance of biomedical implants, ensuring longer-lasting and more effective solutions for patients.

PUBLICATION ACHIEVEMENTS 📚

Throughout her career, Yaling has published extensively in leading scientific journals. Her studies have explored a variety of topics, including the mechanical and tribological properties of polymer coatings and hydrogels on titanium alloys. Notable publications include her work on hydrogel coatings embedded with nanoparticles and the development of biocompatible coatings for biomedical applications.

INNOVATIVE APPROACHES TO SURFACE MODIFICATION 🛠

Yaling's innovative approach to surface modification has paved the way for breakthroughs in artificial joint technology. By utilizing polymers and nanoparticles, she has developed surface coatings that significantly improve the lubrication and wear resistance of materials used in medical implants. Her interdisciplinary work bridges the gap between materials science and biomedicine.

CONFERENCES AND COLLABORATIONS 🌐

Yaling is an active participant in international conferences, where she shares her latest research findings and collaborates with other leading experts in her field. Her contributions to the World Tribology Congress and other notable conferences have established her as a key figure in advancing the understanding of biotribological systems and materials performance under stress.

FUTURE DIRECTIONS IN BIOTRIBOLOGY 🚀

As Yaling continues her work in biotribology and surface engineering, her future research aims to explore new materials and techniques that can further improve the performance of artificial implants. Her goal is to develop sustainable and high-performance biomaterials that can meet the demands of the medical field, contributing to the next generation of healthcare solutions.

NOTABLE PUBLICATION

Title: A Cell Wall-Targeted Organic-Inorganic Hybrid Nano-Catcher for Ultrafast Capture and SERS Detection of Invasive Fungi
Authors: Xu, Y., Gu, F., Hu, S., Chen, Z., Yang, Y.
Journal: Biosensors and Bioelectronics
Year: 2023

Title: Click Chemistry for 3D Bioprinting
Authors: Nie, L., Sun, Y., Okoro, O.V., Jiang, G., Shavandi, A.
Journal: Materials Horizons
Year: 2023

Title: Fabrication and Desired Properties of Conductive Hydrogel Dressings for Wound Healing
Authors: Nie, L., Wei, Q., Li, J., Shavandi, A., Jing, S.
Journal: RSC Advances
Year: 2023

Title: Research Advance in Application of Surface Grafting Modification of Polyethylene
Authors: Deng, Y.-L., Li, Y.-W.-C., Xu, Y., Gao, C.-H., Wang, Y.-X.
Journal: Surface Technology
Year: 2023

Title: Graphene Oxide-Reinforced Alginate/Gelatin Hydrogel via Schiff-Base Bond and Thiol-Michael Addition for Bone Regeneration
Authors: Ding, P., Okoro, O.V., Sun, Y., Shavandi, A., Nie, L.
Journal: Materials Today Communications
Year: 2022

Xin Lai – Mechanical Engineering – Best Researcher Award

Wuhan University of Technology – China

AUTHOR PROFILE

SCOPUS

🔬 SIGNIFICANCE OF RESEARCH

Fluid-structure interaction (FSI) problems present a fundamental challenge in Civil and Environmental Engineering, particularly when dealing with complex scenarios involving large geometric deformations and material failure. Accurate modeling of these interactions is crucial for designing resilient infrastructure, predicting structural behavior under extreme conditions, and enhancing safety measures. My research introduces a groundbreaking approach that combines Non-Ordinary State-Based Peridynamics (NOSB-PD) with Updated Lagrangian Particle Hydrodynamics (ULPH) to address these challenges and improve the modeling of fluid-structure interactions.

🔍 PROBLEM ADDRESSED

Traditional methods for solving fluid-structure interaction issues often struggle with handling discontinuities and large deformations in materials, resulting in inaccuracies and computational instability. The demand for a robust, stable, and accurate method to simulate these interactions, especially for Newtonian fluids, is critical for advancing engineering practices. My research fills this gap by developing a coupled framework that integrates NOSB-PD and ULPH, offering a novel perspective and solution to fluid-structure interaction problems.

🛠️ METHODOLOGY EMPLOYED

The methodology developed integrates NOSB-PD theory to describe the deformation and fracture of solid materials with ULPH to represent the flow of Newtonian fluids. NOSB-PD is particularly effective in handling discontinuities and fractures in solids, while ULPH provides superior computational accuracy for fluid dynamics. By coupling these methods, my approach effectively models fluid-structure interactions with large deformations and material failure, enhancing the accuracy and stability of simulations.

💡 KEY INNOVATION

A major innovation of this research is the development of a fluid-structure coupling algorithm that uses pressure as the transmission medium to manage the interface between fluids and structures. This approach ensures robust and stable simulations, accurately representing the dynamic interactions between fluids and structures under varying conditions. This advancement significantly improves the reliability of simulations in complex scenarios.

🌍 IMPACT ON ENGINEERING PRACTICES

The ULPH-NOSBPD coupling approach represents a significant contribution to the field of Civil and Environmental Engineering. It provides a novel framework for accurately simulating fluid-structure interactions, with potential applications in infrastructure design and environmental management. This research addresses long-standing challenges in the field and offers innovative solutions that advance engineering practices.

🏆 HONOR AND FUTURE VISION

Being considered for the “Best Researcher Award” is a profound honor, and I am grateful for the opportunity to showcase my work. I am committed to advancing the field of Civil and Environmental Engineering and contributing to the continued development of innovative solutions. Thank you for considering my nomination, and I look forward to furthering our understanding and application of fluid-structure interactions through my research.

NOTABLE PUBLICATIONS

Peridynamics simulations of geomaterial fragmentation by impulse loads

Authors: X. Lai, B. Ren, H. Fan, S. Li, C.T. Wu, R.A. Regueiro, L. Liu

Journal: International Journal for Numerical and Analytical Methods in Geomechanics

Year: 2015

A non-ordinary state-based peridynamics modeling of fractures in quasi-brittle materials

Authors: X. Lai, L. Liu, S. Li, M. Zeleke, Q. Liu, Z. Wang

Journal: International Journal of Impact Engineering

Year: 2018

A peridynamics–SPH coupling approach to simulate soil fragmentation induced by shock waves

Authors: B. Ren, H. Fan, G.L. Bergel, R.A. Regueiro, X. Lai, S. Li

Journal: Computational Mechanics

Year: 2015

Higher-order nonlocal theory of Updated Lagrangian Particle Hydrodynamics (ULPH) and simulations of multiphase flows

Authors: J. Yan, S. Li, X. Kan, A.M. Zhang, X. Lai

Journal: Computer Methods in Applied Mechanics and Engineering

Year: 2020

Peridynamic stress is the static first Piola–Kirchhoff Virial stress

Authors: J. Li, S. Li, X. Lai, L. Liu

Journal: International Journal of Solids and Structures

Year: 2024