Xuemei Wei | Materials Science and Engineering | Best Paper Award

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Dr Xuemei Wei | Materials Science and Engineering | Best Paper Award







Assistant Researcher, Shaoxing University, China


Dr. Xuemei Wei is an accomplished researcher specializing in metal-organic chemistry and catalysis. She holds a Ph.D. in Physical Chemistry from the Lanzhou Institute of Chemical Physics, Chinese Academy of Sciences. Her expertise lies in the development of nano-catalytic materials for environmental and energy applications. With over 12 SCI publications in high-impact journals, she has made significant contributions to catalyst design and chemical transformations. Currently, she serves as an Assistant Researcher at Shaoxing University, where she advances research in pharmaceutical and chemical sciences. Her work integrates innovative nanomaterials to address environmental challenges and sustainable energy solutions.


PROFESSIONAL PROFILE


Scopus


EDUCATION


πŸŽ“ Ph.D. in Physical Chemistry – Lanzhou Institute of Chemical Physics, Chinese Academy of Sciences (2018-2021)
πŸ“ Thesis: Design and Mechanism of Efficient Carbonylation Catalysts under Ambient Conditions.
πŸŽ“ M.Sc. in Inorganic Chemistry – Inner Mongolia University (2013-2016)
πŸŽ“ B.Sc. in Chemistry – Jilin Normal University (2009-2013)


PROFESSIONAL EXPERIENCE


πŸ”¬ Assistant Researcher – Shaoxing University, College of Chemistry and Chemical Engineering (2021-Present)
πŸ” Focus: Development of nano-catalytic materials for industrial and environmental applications.
πŸ§ͺ R&D Specialist – Changchun Zhongke Haorong New Materials Research Co., Ltd. (2016-2018)
πŸš€ Developed and optimized catalytic materials for large-scale industrial use.


AWARDS & HONORS


πŸ† Recognized for research contributions in metal-organic chemistry.
πŸ“œ Multiple SCI-indexed publications in top-tier journals.
🌍 Acknowledged for innovative approaches in environmental catalysis.


RESEARCH FOCUS


πŸ§ͺ Catalysis Under Ambient Conditions: Development of carbonylation catalysts for industrial applications.
🌱 Environmental Nanomaterials: Engineering nanomaterials for pollutant degradation and remediation.
⚑ Sustainable Energy Catalysis: Exploring hydrodeoxygenation reactions for green chemistry solutions.


PUBLICATION TOP NOTES


πŸ“„ Turning on Ambient Conditions Hydrodeoxygenation of Biobased Aromatic Alcohols – Energy Conversion and Management (2025)
πŸ“„ Construction of MXene-loaded Nanoscale Zero-Valent Iron for ReO4-/TcO4- Sequestration – Separation and Purification Technology (2024)
πŸ“„ Deciphering the Facet-Dependent Scavenging Potential of Ξ±-Fe2O3 Nanocrystals – Applied Surface Science (2024)
πŸ“„ Crucial Size Effect on Dicarbonylation of Acetylene Over Pd/CsHPMo Catalysts – Dalton Transactions (2024)
πŸ“„ Targeting Phosphodiesterase 4 as a Therapeutic Strategy for Cognitive Improvement – Bioorganic Chemistry (2023)
πŸ“„ Vesicular BiVO4 Nanostructures Modified by g-C3N4 Quantum Dots – Materials Science in Semiconductor Processing (2024)
πŸ“„ Synergistic Effect of Hematite Facet and Pd Nanocluster for Acetylene Dicarbonylation – Molecular Catalysis (2021)
πŸ“„ Strong Metal-Support Interactions Between Palladium Nanoclusters and Hematite – New Journal of Chemistry (2020)
πŸ“„ Highly Efficient Selective Dicarbonylation of Acetylene Catalyzed by Palladium Nanosheets – New Journal of Chemistry (2020)
πŸ“„ Catalyst in Acetylene Carbonylation: From Homogeneous to Heterogeneous – Progress in Chemistry (2020)
πŸ“„ Advances in Research on Structure-Activity Relationship in Hydrogenation Catalysts – Chemical Industry and Engineering Progress (2020)
πŸ“„ Support Morphology-Dependent Catalytic Activity of Co/CeO2 for Phenol Hydrogenation – New Journal of Chemistry (2020)


CONCLUSION


Dr. Xuemei Wei is a leading researcher in catalysis and nanomaterials, making significant strides in environmental and sustainable chemistry. Her contributions to metal-organic chemistry and catalytic performance have earned her recognition in top scientific journals. As an Assistant Researcher at Shaoxing University, she continues to develop innovative solutions for industrial and environmental challenges. πŸš€πŸ”¬





	


	

	






	
	

		


Patrick Chernjavsky | Additive Manufacturing | Best Researcher Award
			

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Mr Patrick Chernjavsky | Additive Manufacturing | Best Researcher Award


Research Assistant, Worcester Polytechnic Institute, United States


Patrick Chernjavsky is a Ph.D. candidate in Mechanical & Materials Engineering at Worcester Polytechnic Institute (WPI), specializing in advanced manufacturing, design for manufacturing, and surface metrology. His research focuses on material characterization, corrosion control, and optimizing manufacturing processes for enhanced performance and durability. With extensive experience in metallurgical engineering, additive manufacturing, and tribology, Patrick has contributed significantly to industry and academia through innovative projects and research publications. His work in material removal rate analysis, flexible spindle polishing, and vibration control has been recognized in leading journals. Patrick has also interned at Saint-Gobain, Liquid Piston, and NAWCAD, where he developed advanced coatings, automated analysis tools, and thermo-mechanical models. His contributions to aerospace, medical devices, and energy systems showcase his interdisciplinary expertise. Patrick continues to advance precision manufacturing technologies through research, experimentation, and industry collaborations.


PROFESSIONAL PROFILE


Google Scholar


STRENGTHS FOR THE AWARD


βœ… Diverse Research Portfolio: Patrick Chernjavsky has an extensive research background spanning Advanced Manufacturing, Surface Polishing, and Additive Manufacturing, making significant contributions to both industry and academia.
βœ… High-Impact Publications: His work is published in reputable journals and conferences, covering grinding processes, HydroFlex polishing, vibration control, and tribological coatings, demonstrating strong experimental and analytical expertise.
βœ… Industrial and Government Research Experience: His internships at Liquid Piston, Saint-Gobain, and NAWCAD highlight his ability to bridge academic research with real-world engineering applications, including materials selection, coatings, and mechanical performance testing.
βœ… Innovation and Problem-Solving: Contributions to corrosion control, wear resistance, and material removal rate optimization show a strong problem-solving ability in high-performance materials and surface metrology.
βœ… Recognition and Security Clearance: His scholarship award for developing an automated vibration analysis tool for aircraft components and SECRET-level security clearance underline his trustworthiness and excellence in classified research.


AREAS FOR IMPROVEMENTS


πŸ”Ή Higher Citation Impact: While his research is well-regarded, increasing citations and extending collaborations in emerging materials science and sustainable manufacturing could strengthen his influence.
πŸ”Ή Broader Research Leadership: Leading more interdisciplinary projects or securing external funding for research grants could further solidify his standing as a top researcher.
πŸ”Ή Industry-Academia Partnerships: Expanding on industry collaborations for real-world applications, particularly in robotic surface finishing and aerospace materials, could enhance research applicability.


EDUCATION πŸŽ“


Patrick Chernjavsky is pursuing a Doctor of Philosophy in Mechanical & Materials Engineering at Worcester Polytechnic Institute (WPI), Worcester, Massachusetts, with an expected completion in May 2025. His research areas include advanced manufacturing, surface metrology, design for manufacturing, and corrosion control. Patrick has also developed expertise in experimental techniques such as non-destructive CT, profilometry, XRD, SEM, and wear testing. Prior to WPI, he actively participated in engineering projects, including drone design and hydropower device development. His academic journey is complemented by certifications such as Engineering Simulation with ANSYS (2024), reinforcing his proficiency in simulation tools. His educational background has laid a strong foundation for his research contributions to material characterization, tribology, and manufacturing processes.


EXPERIENCE 🏭


Patrick Chernjavsky has gained diverse industrial and research experience through multiple internships and assistantships. As a Metallurgical Engineering Intern at Liquid Piston (December 2024 – March 2025), he worked on advanced coating tribopairs and surface crosshatch designs for rotary engine seals. At Saint-Gobain (May 2021 – August 2021), he collaborated on thermo-mechanical modeling of grinding processes and conducted validation testing. During his tenure at NAWCAD (June 2019 – February 2021), he developed an automated vibration analysis tool for aircraft component testing, earning a scholarship award. Additionally, as a Research Assistant at WPI, he has contributed to various projects in additive manufacturing, polishing, and tribology. His experience spans material characterization, design for manufacturing, and aerospace engineering, bridging the gap between theoretical research and practical applications.


AWARDS & HONORS πŸ†


Patrick Chernjavsky has been recognized for his contributions to mechanical engineering and research innovation. He received a scholarship award for developing an automated vibration analysis tool at NAWCAD, demonstrating excellence in aerospace engineering. His work in tribology and material characterization has been featured in leading manufacturing and medical device conferences. Additionally, his research contributions in polishing techniques, material removal rate analysis, and corrosion control have been cited in esteemed journals. Patrick’s interdisciplinary expertise in additive manufacturing, advanced coatings, and precision engineering continues to earn accolades in academic and industrial circles. His commitment to innovation and research excellence underscores his dedication to advancing mechanical and materials engineering.


RESEARCH FOCUS πŸ”¬


Patrick Chernjavsky’s research focuses on advanced manufacturing, tribology, and precision surface finishing. His work explores material removal dynamics, flexible spindle polishing, and vibration control for industrial applications. He investigates innovative coating techniques for wear resistance and friction reduction, optimizing material properties for aerospace and medical applications. His studies in hydrodynamic flexible spindle (HydroFlex) polishing have led to advancements in internal surface finishing for high-aspect-ratio channels. Patrick also explores experimental techniques such as SEM, XRD, and profilometry to assess surface integrity. His interdisciplinary approach combines experimental analysis, computational modeling, and real-world validation, contributing to high-performance manufacturing and material durability.


PUBLICATION TOP NOTES πŸ“„


    

  • Experimental Investigation of the Material Removal Rate in Grinding of Calcified Plaque by Rotational Atherectomy
    • 

  • Hydrodynamic Flexible Spindle (HydroFlex) Polishing for Internal Surfaces of Complex Channels with High Aspect Ratio
    • 

  • Experimental Investigation of the Calcified Plaque Material Removal Rate in Coronary Rotational Atherectomy
    • 

  • Vibration Control Coupler Design for Robot Learning From Human Polishing
    • 

  • Grit Size Effect on HydroFlex Polishing Dynamics and Performance
    • 

  • Hydrodynamic Flexible Spindle (HydroFlex) Polishing of Turbine Blade Internal Cooling Channels for Oxide Removal
    • 

  • Creation of a Fish-Friendly Aquatic Hydropower Device Using an Oscillating Hydrofoil
    • 

  • Creation and Distribution of Monetized Online Content for Old Sturbridge Village’s Virtual Village
    • 

  • Monroe Community College Drone Design Team
    • 



CONCLUSION


Patrick Chernjavsky is a strong candidate for the Best Researcher Award due to his expertise in advanced manufacturing, tribology, and surface metrology, combined with notable industrial experience and impactful publications. With further research leadership and industry partnerships, he has the potential to be a leading figure in the field of materials science and engineering. πŸš€

	


	

	






	
	

		


Miranda Fateri | Space Manufacturing | Best Researcher Award
			

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Prof. Dr Miranda Fateri | Space Manufacturing | Best Researcher Award


Professor, Aalen University, Germany


Miranda Fateri is a professor at Aalen University, specializing in Additive Manufacturing, Selective Laser Melting, and In-Situ Resource Utilization (ISRU) for space applications. With a strong background in engineering and material sciences, she has played a vital role in pioneering research on lunar regolith processing and 3D printing technologies for extraterrestrial environments. She has contributed to multiple ESA and Horizon 2020 projects, focusing on sustainable manufacturing solutions for space exploration. Her work on solar sintering, microwave additive manufacturing, and lunar regolith utilization has earned her global recognition. She has also supervised over 30 technology readiness level (TRL) projects and managed significant research funding exceeding €2 million.


PROFESSIONAL PROFILE


Google Scholar


Scopus


STRENGTHS FOR THE AWARD


    

  1. Extensive Research Contributions – Dr. Fateri has a strong publication record in Additive Manufacturing, Selective Laser Melting, Lunar Regolith, and Microgravity applications. Their research significantly contributes to space exploration and sustainable manufacturing.
    2. 

  2. Significant Funding and Awards – Secured over €2 million in research grants, including funding from ESA, H2020, DLR, and Innovate-Sand Project, demonstrating strong research impact and leadership.
    3. 

  3. Innovative Space Applications – Their work on lunar regolith sintering, 3D printing for space applications, and in-situ resource utilization (ISRU) supports future Moon and Mars missions, which is a groundbreaking area in aerospace engineering.
    4. 

  4. Experimental Leadership – Dr. Fateri has played a key role in experiments for the International Space Station (ISS), ESA, and DLR projects, demonstrating the ability to translate theoretical research into real-world space applications.
    5. 

  5. Mentorship & Supervision – Supervised 30+ projects under ESA Spaceship-EAC, contributing to the next generation of researchers in additive manufacturing and space technology.
    6. 

  6. Industry Collaboration – Strong partnerships with DLR, ESA, and international research institutions showcase their ability to work on large-scale projects with global impact.
    7. 



AREAS FOR IMPROVEMENT


    

  1. Broader Industrial Impact – While their research is highly specialized in space manufacturing, expanding applications of their findings to terrestrial industries (e.g., sustainable construction, biomedical applications of AM) could further enhance impact.
    2. 

  2. Interdisciplinary Outreach – Engaging in more cross-disciplinary collaborations with materials science, environmental engineering, and AI-based optimization could strengthen research versatility.
    3. 

  3. Increased Citation Impact – While well-cited, increasing high-impact journal publications and patent applications could further solidify their status as a leading researcher.
    4. 



EDUCATION


πŸŽ“ Ph.D. in Mechanical Engineering – RWTH Aachen University

πŸŽ“ M.Sc. in Mechanical Engineering – RWTH Aachen University

πŸŽ“ B.Sc. in Mechanical Engineering – University of Tehran

Her academic journey began at the University of Tehran, where she completed her bachelor’s degree in Mechanical Engineering. She then pursued her master’s and doctoral studies at RWTH Aachen University, focusing on advanced manufacturing techniques, material processing, and space technology applications. Her doctoral research contributed to the development of additive manufacturing techniques for extraterrestrial environments, particularly selective laser melting of lunar regolith.


EXPERIENCE


πŸ›° Professor at Aalen University – Teaching and research in additive manufacturing

πŸš€ Engineering Lab Head at DLR-Cologne – Responsible for experimental designs, equipment management, and risk assessments

πŸ— Additive Manufacturing Lab Lead at FH Aachen – Supervised projects, managed safety protocols, and conducted research on advanced manufacturing techniques

πŸ”¬ ESA Spaceship-EAC Program – Supervised 30+ research projects focused on space manufacturing

🌍 Horizon’s ISS Experiment – Developed additive manufacturing solutions for space applications, including on the ISS

πŸ“‘ Project Lead for ESA and H2020 Programs – Focused on lunar regolith 3D printing, energy storage, and extraterrestrial construction


AWARDS AND HONORS


πŸ† Research Grants & Awards – Secured over €2 million in research funding

πŸ… ESA-ESTEC OSIP Idea Calls – Recognized for innovative lunar regolith utilization projects

πŸ₯‡ Horizon 2020 Regolight Project – Key contributor to the development of solar sintering techniques for lunar applications

πŸš€ DLR-Technology Marketing Innovate-Sand Project – Led research on Sahara sand-based additive manufacturing

πŸ”¬ ESA-NPI Project Award – Developed powder-based 3D printing solutions for microgravity environments

🌌 Explor-Stiftung Kessler & Co. Grant – Advanced research in 3D-printed pneumatic actuators


RESEARCH FOCUS


πŸ”„ Additive Manufacturing – Advancing 3D printing for space applications

πŸŒ• Lunar Regolith Processing – Developing sustainable construction methods for the Moon

πŸ›° Microgravity Manufacturing – Creating novel solutions for in-space fabrication

β˜€ Solar Sintering – Harnessing solar energy for extraterrestrial manufacturing

βš™ Material Science – Investigating new materials for high-performance applications in space


PUBLICATION TOP NOTES


πŸ“„ Process parameters development of selective laser melting of lunar regolith for on‐site manufacturing applications

πŸ“„ Solar sintering for lunar additive manufacturing

πŸ“„ Selective laser melting of soda‐lime glass powder

πŸ“„ EAC-1A: A novel large-volume lunar regolith simulant

πŸ“„ Experimental investigation on selective laser melting of glass

πŸ“„ Feasibility study on additive manufacturing of recyclable objects for space applications

πŸ“„ Investigation of the sintering and melting of JSC-2A lunar regolith simulant

πŸ“„ Thermal properties of processed lunar regolith simulant

πŸ“„ Advancing solar sintering for building a base on the Moon

πŸ“„ Experimental investigation of selective laser melting of lunar regolith for in-situ applications

πŸ“„ **Investigation on wetting and melting behavior of lunar regolith simulant for additive manufacturing


CONCLUSION


Dr. Miranda Fateri is a strong candidate for the Best Researcher Award, given their pioneering work in Additive Manufacturing for Space Applications, Microgravity Research, and Lunar Resource Utilization. Their contributions to ESA, ISS, and DLR projects showcase scientific leadership, innovation, and global impact. Expanding industrial applications and interdisciplinary collaborations could further elevate their standing in the field.

	


	

	






	
	

		


Sharu Bhagavathi Kandy | Additive Manufacturing | Innovations in Materials Engineering Award
			

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Dr Sharu Bhagavathi Kandy | Additive Manufacturing | Innovations in Materials Engineering Award


Assistant Professor, NIT Calicut/ University of California Los Angeles, India


Dr. Sharu Bhagavathi Kandy is an Assistant Professor in the Department of Mechanical Engineering at the National Institute of Technology Calicut. With a rich academic background and international experience, he specializes in additive manufacturing, complex fluid rheology, colloids and interfacial science, and nanomaterials. Sharu has worked at prestigious institutions like UCLA, IIT Bombay, and Monash University. His work is recognized globally, especially in the fields of nanomaterials and material science. In addition to teaching and research, he has also contributed to several high-impact publications and patents, solidifying his position as a leading expert in his fields.


PROFESSIONAL PROFILE


Google Scholar


Scopus


STRENGTHS FOR THE AWARD


    

  1. Academic Excellence: Sharu Bhagavathi Kandy has an impressive educational background, having completed a Ph.D. in Materials Science and Engineering from prestigious institutions like IITB-Monash Research Academy, Indian Institute of Technology Bombay, and Monash University Melbourne. The academic rigor is reflected in the CGPA of 9.75/10 in the Ph.D. program, which is exceptional.
    2. 

  2. Strong Professional Experience: With roles ranging from Assistant Professor at NIT Calicut to Postdoctoral Scholar at UCLA, Kandy has demonstrated expertise across a wide spectrum of academic and research positions. The role as a Lecturer at UCLA and experience as a Graduate Teaching Assistant at IITB-Monash Research Academy further enhances their profile.
    3. 

  3. Research Output: Kandy has a diverse and impactful research portfolio, with a focus on complex fluid rheology, colloids, interfacial science, CNTs, and 2D nanomaterials. Several publications in reputable journals such as RSC Advances, ACS Omega, and Langmuir further solidify their expertise in the field.
    4. 

  4. Innovative Contributions: The CAS Registry Innovator Award from the American Chemical Society, granted for the novel compound synthesized (CAS RN 2273765-17-4), showcases Kandy’s ability to push boundaries in materials science. Additionally, a wide range of cutting-edge research topics, including 3D printing applications, are highly relevant in today’s engineering landscape.
    5. 

  5. International Recognition: Their research has been cited widely, with notable works on the aggregation behavior in Portlandite suspensions and the development of thermoresponsive suspensions. The global collaboration through roles in leading institutions such as UCLA and Monash University adds to their international research presence.
    6. 

  6. Award Achievements: Receiving multiple academic excellence awards, including the Academic Proficiency Award during both undergraduate and postgraduate studies, highlights a consistent commitment to excellence throughout their academic career.
    7. 



AREAS FOR IMPROVEMENT


    

  1. Broader Interdisciplinary Outreach: While Kandy’s work in nanomaterials, fluid dynamics, and 3D printing is innovative, expanding research into interdisciplinary areas such as sustainable materials or renewable energy could further broaden their impact.
    2. 

  2. Increasing Public Engagement: Enhancing engagement with the broader scientific community through public science outreach, blog posts, or collaborations with industries working on practical applications of their research would help amplify their work’s societal impact.
    3. 

  3. Collaboration and Mentoring: Though Kandy has worked in high-impact research settings, an increased focus on mentoring junior researchers and fostering new collaborations with experts in related fields could lead to the development of multi-disciplinary research programs.
    4. 

  4. Funding and Grants: Actively pursuing more grants and funding opportunities to support larger-scale, collaborative projects would further enhance Kandy’s research profile.
    5. 



EDUCATION


Dr. Sharu Bhagavathi Kandy holds a Ph.D. in Materials Science and Engineering from the IITB-Monash Research Academy (IIT Bombay and Monash University) with a remarkable CGPA of 9.75/10 (March 2018). He completed his Master of Technology in Nano Science and Technology from the National Institute of Technology Calicut in 2011, securing a CGPA of 9.03/10. Earlier, he earned his Bachelor of Technology in Mechanical Engineering from the Government Engineering College Kozhikode, University of Calicut, graduating with 77.25%. His educational journey has been marked by excellence and a strong foundation in materials science, nanotechnology, and engineering.


EXPERIENCE


Dr. Sharu Bhagavathi Kandy is currently an Assistant Professor at the Department of Mechanical Engineering, National Institute of Technology Calicut (Jan 2023 – present). Prior to this, he was a Postdoctoral Scholar at the University of California Los Angeles (UCLA) in the Department of Civil and Environmental Engineering (July 2019 – Dec 2023). He also served as a Lecturer in the same department for a brief period (Jan – March 2020). Dr. Kandy’s earlier roles include Assistant Professor at VIT Vellore, where he taught from June 2017 to June 2019. Additionally, he has held positions at IIT Bombay and Monash University. His teaching expertise includes engineering mechanics and material science, and his research contributions have been recognized internationally.


AWARDS AND HONORSΒ 


Dr. Sharu Bhagavathi Kandy has earned numerous accolades throughout his career. He received the CAS Registry Innovator Award from the American Chemical Society in 2020 for synthesizing a novel compound (CAS RN 2273765-17-4). His academic excellence was recognized by securing the 18th rank in the Graduate Aptitude Test in Engineering (GATE) 2012 in India. He was awarded the Academic Proficiency Award by NIT Calicut (2009-2010) for outstanding performance during his postgraduate studies. Additionally, Dr. Kandy received the Academic Proficiency Award from the Government Engineering College Kozhikode during his undergraduate studies (2006). He was also the recipient of the Malayalee Engineers Association North America (MEANA) Merit Scholarship, showcasing his recognition in both India and the international academic community.


RESEARCH FOCUSΒ 


Dr. Sharu Bhagavathi Kandy’s research focuses on additive manufacturing, complex fluid rheology, colloids, and interfacial science. He is particularly interested in nanomaterials such as carbon nanotubes (CNTs) and 2D nanomaterials. His work explores the behavior of highly concentrated emulsions and suspensions, contributing significantly to understanding the microstructure, rheological characteristics, and flow behavior of these materials. He has applied his research to the development of advanced thermoresponsive suspension composites for 3D printing. His recent studies also focus on the aggregation and stiffening behavior of concentrated mineral suspensions and their implications for construction materials. Dr. Kandy’s research has led to several patents and high-impact publications, driving innovation in the fields of material science, nanotechnology, and engineering applications.


PUBLICATION TOP NOTES


    

  • Molybdenum disulfide nanoflakes through Li-AHA assisted exfoliation in an aqueous medium πŸ§ͺ
    • 

  • Effect of organic modification on multiwalled carbon nanotube dispersions in highly concentrated emulsions πŸ§ͺ
    • 

  • Development of microstructure and evolution of rheological characteristics of a highly concentrated emulsion during emulsification 🌊
    • 

  • Effect of incorporation of multiwalled carbon nanotubes on the microstructure and flow behavior of highly concentrated emulsions 🌊
    • 

  • Temperature-induced aggregation in portlandite suspensions 🌑
    • 

  • Ultrafast stiffening of concentrated thermoresponsive mineral suspensions πŸ—
    • 

  • Electrosteric control of the aggregation and yielding behavior of concentrated portlandite suspensions πŸ—
    • 

  • Thermally stimulated stiffening and fly ash’s alkaline activation by Ca (OH) 2 addition facilitates 3D-printing πŸ—
    • 

  • Thermoresponsive suspension composites for 3D printing πŸ–¨
    • 

  • Ultrafast stiffening of concentrated thermoresponsive polymer-mineral suspensions 🌑
    • 

  • Temperature-Induced Aggregation and Rheological Response of Concentrated Portlandite Suspensions πŸ”¬
    • 

  • Temperatureβˆ’structureβˆ’rheology response of portlandite suspensions πŸ”¬
    • 

  • Temperature-induced heteroaggregation in polydisperse portlandite suspensions πŸ”¬
    • 

  • Dispersing nano-and micro-sized portlandite particulates via electrosteric exclusion at short screening lengths πŸ”¬
    • 

  • Microstructure development and rheological characteristics of highly concentrated emulsions during emulsification πŸ§ͺ
    • 

  • Convective heat transfer characteristics of Ti02 Nanofluid at high pressures πŸ”₯
    • 































CONCLUSION


Sharu Bhagavathi Kandy is highly deserving of the Best Researcher Award due to their exceptional academic and professional background, innovative research contributions, international recognition, and notable achievements. Their work on complex fluid rheology and 3D printing is groundbreaking, and their ability to push the boundaries of materials science is impressive. With a few improvements in outreach, collaboration, and funding efforts, Kandy can continue to expand their impact in both academia and industry.