Dr. M. Ramamurthy | Experimental Methods | Best Researcher Award

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Dr. M. Ramamurthy | Experimental Methods | Best Researcher Award

Assistant Professor | AMET University | India

Dr. M. Ramamurthy is a highly accomplished academician and researcher with extensive experience in Experimental Methods applied to mechanical and manufacturing engineering. His professional journey spans across several reputed engineering institutions, where he has contributed to Experimental Methods in teaching, research, and curriculum design. Holding a Ph.D. from Anna University with a focus on friction stir welding, Dr. M. Ramamurthy has published multiple papers in international journals emphasizing Experimental Methods for optimizing welding parameters, material characterization, and process analysis. His expertise extends to Experimental Methods in advanced materials, composite fabrication, and surface modification, reflecting a strong grasp of both theoretical and practical domains. He has participated in numerous conferences and workshops, showcasing his innovative applications of Experimental Methods in materials science and production engineering. Recognized for his contributions, he holds patents and authored book chapters on Experimental Methods for sustainable material development. His professional affiliations include ISTE, IAENG, and PMAI, demonstrating his commitment to continuous learning and collaboration. His research skills encompass Experimental Methods involving friction stir processes, multi-objective optimization, and mechanical testing. Dr. M. Ramamurthy’s awards and honors reflect his dedication to innovation and knowledge dissemination in Experimental Methods. With a balanced blend of academic and industrial exposure, he consistently integrates Experimental Methods into education, research, and technology development. In conclusion, Dr. M. Ramamurthy’s distinguished career exemplifies excellence in Experimental Methods, advancing engineering practices and inspiring future researchers.

Profiles: Google Scholar | ORCID

Featured Publications

1. Ramamurthy, M., Balasubramanian, P., Senthilkumar, N., & G. (2022). Influence of process parameters on the microstructure and mechanical properties of friction stir welds of AA2014 and AA6063 aluminium alloys using response surface methodology. Materials Research Express, 9, 70.

2. Senthilkumar, N., Thanikasalam, A., Stalin, K., Ramamurthy, M., & Lazar, P. (2024). Mechanical characterization of epoxy-nanoclay-kenaf fiber polymer composites. International Conference on Advanced Materials Manufacturing and Structures.

3. Ramamurthy, M., & Balasubramanian, P. (2022). Parametric optimization in friction stir joining of AA2014 and AA6061 alloys through entropy based multiobjective GRA approach. Materials Today: Proceedings, 59, 1249–1255.

4. Ramamurthy, M., Vasanthkumar, N. P., Perumal, G., & Senthilkumar, N. (2025). Formulation and features of chitosan and natural fiber blended bio-composite towards environmental sustainability. Journal of Environmental Nanotechnology, 14(1), 104–112.

5. Senthilkumar, N., Thanikasalam, A., Stalin, K., Ramamurthy, M., & Lazar, P. (2024). Thermal studies on palm fibre and rice husk ash-reinforced epoxy resin composite. International Conference on Advanced Materials Manufacturing and Structures.

Dr. Bin Song | Experimental Methods | Best Researcher Award

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Dr. Bin Song | Experimental Methods | Best Researcher Award

Associate Professor | Southwest Petroleum University | China

Dr. Bin Song, an accomplished scholar in Experimental Methods, holds a Doctor of Engineering and serves as an Associate Researcher and Master’s Supervisor at Southwest Petroleum University. His work in Experimental Methods has greatly advanced gas safety and integrity assessment, hydrogen storage and transportation, and efficient utilization processes. Through his innovative use of Experimental Methods, he has produced over twenty high-level publications, sixteen of which are SCI-indexed, demonstrating his consistent excellence in research dissemination. His involvement in Experimental Methods also extends to securing four national invention patents, one of which achieved successful technological transformation, showcasing his strong applied research capabilities. Furthermore, he has contributed to the compilation of two industry and township standards, reinforcing the practical impact of his Experimental Methods-based investigations. His recognition in the scientific community stems from his ability to integrate Experimental Methods with engineering innovation, improving safety, performance, and sustainability in petroleum and hydrogen systems. His analytical expertise, technical precision, and interdisciplinary collaboration highlight his strong research skills and commitment to advancing Experimental Methods for industrial and academic excellence. Dr. Bin Song continues to inspire future researchers through his dedication to innovation, knowledge transfer, and technological development in Experimental Methods-driven research. 207 Citations, 18 Documents, 7 h-index.

Profile: Scopus

Featured Publication

1. Novel method for optimizing emergency response facility layouts in gas pipeline networks. (2025). Journal of Pipeline Systems Engineering and Practice.

Dr. hardeep kaur | Experimental Methods | Best Researcher Award

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Dr. Hardeep kaur | Experimental Methods | Best Researcher Award

Assistant Professor at Khalsa College | India

Dr. Hardeep kaur is a dedicated researcher in organic chemistry with expertise in drug discovery, fluorescence probes, and computational studies. Through innovative Experimental Methods, she integrates traditional synthesis with in silico modeling to address health challenges like malaria and tuberculosis. Her work on molecular recognition of heavy metals and biological targets highlights the power of Experimental Methods in both diagnostics and therapeutics. As an assistant professor at khalsa college, she combines academic guidance, mentoring, and research leadership with extensive use of Experimental Methods. Her collaborations have advanced applied chemistry, bridging theoretical understanding with practical Experimental Methods. Her consistent contributions and awards demonstrate excellence and dedication, reflecting her continuous pursuit of innovation through rigorous Experimental Methods.

Professional Profiles 

Scopus Profile | ORCID Profile

Education 

Dr. Hardeep kaur holds a strong academic foundation in chemistry, with advanced training that shaped her expertise in Experimental Methods. From undergraduate honors to postgraduate specialization and doctoral research, her education emphasized organic synthesis, molecular design, and mechanistic studies through Experimental Methods. Guided by leading chemists, she developed skills in complex reaction pathways, spectroscopic analysis, and computational approaches that rely heavily on Experimental Methods. Her academic journey refined critical thinking and innovative strategies, incorporating both theoretical principles and Experimental Methods to solve chemical and biological challenges. This solid educational background empowers her to teach, supervise, and inspire future scientists while continuing her own research through advanced Experimental Methods in organic and medicinal chemistry.

Experience 

Assistant professor at khalsa college, Dr. Hardeep kaurhas excelled in teaching, research, and departmental leadership using Experimental Methods as a central tool. She manages academic programs, oversees innovation initiatives, and contributes to institutional committees while guiding students in Experimental Methods. Her professional journey includes supervising numerous postgraduate theses and coordinating seminars, ensuring students develop hands-on skills with modern Experimental Methods. She actively collaborates with academic and industrial partners to translate Experimental Methods into practical solutions, fostering interdisciplinary projects. This extensive professional experience demonstrates her capacity to merge classroom instruction, administrative leadership, and high-impact research into a seamless practice of chemistry through consistent application of Experimental Methods.

Research Interest 

Dr. Hardeep kaur’s research interests revolve around drug discovery, bioactive heterocycles, molecular sensors, and computational chemistry, all enriched by Experimental Methods. She focuses on designing antiplasmodial and antimycobacterial compounds, employing Experimental Methods to optimize synthesis and evaluate biological mechanisms. Her work on fluorescence probes for heavy metal detection utilizes Experimental Methods to develop selective and sensitive systems for environmental and biomedical use. Additionally, her research explores Density Functional Theory (DFT) to complement Experimental Methods, providing mechanistic insight. By integrating Experimental Methods with theoretical modeling, her investigations advance both academic understanding and translational applications in medicinal chemistry, environmental sensing, and advanced material development, maintaining Experimental Methods as a foundation of her scientific contributions.

Award and Honor

Dr. Hardeep kaur has earned recognition for academic excellence, impactful research, and innovation in chemistry, highlighting her skill in Experimental Methods. Her honors include gold medals, competitive fellowships, and international article citations that showcase the influence of her Experimental Methods-based discoveries. Highly cited works on antimalarial hybrids and chemical sensors confirm the global relevance of her Experimental Methods in both healthcare and analytical sciences. Prestigious awards from scientific societies acknowledge her leadership and innovative approaches that combine creativity with rigorous Experimental Methods. Through national and international appreciation, her career reflects a consistent pattern of achievement, driven by precise, reproducible, and groundbreaking Experimental Methods that set benchmarks in modern organic and medicinal chemistry.

Research Skill

Dr. Hardeep kaur possesses advanced research skills in organic synthesis, analytical techniques, and computational modeling, all grounded in Experimental Methods. She is proficient with spectroscopic tools, chromatographic systems, and molecular docking programs, applying Experimental Methods to characterize compounds, validate hypotheses, and interpret biological activities. Her ability to manage sensitive reagents, inert atmospheres, and reaction optimization demonstrates mastery in practical Experimental Methods. Additionally, her integration of data analysis, visualization, and presentation ensures Experimental Methods translate into impactful publications and collaborations. This comprehensive skill set allows her to solve complex chemical problems, mentor future researchers, and develop novel strategies, all underpinned by her expertise in Experimental Methods that bridge innovation and reproducibility.

Publication Top Notes 

Title: Development of sensitive napthaquinone-pyridine hydrazone based chemosensor for the colorimetric detection of Cu2+ ion in an aqueous solution
Year: 2025
Citations: 2

Title: Exploring the anticancer potential of Lasia spinosa rhizomes: insights from molecular docking and DFT investigations on chlorogenic acid and beyond
Year: 2024
Citations: 0

Conclusion

Dr. Hardeep kaur’s career reflects a harmonious integration of education, research, teaching, and collaboration, powered by Experimental Methods. Her dedication to advancing drug discovery, molecular sensing, and applied organic chemistry showcases the transformative potential of well-designed Experimental Methods. Through her leadership, students and colleagues gain exposure to rigorous Experimental Methods that foster innovation and integrity in science. Her achievements across academia, publications, and recognition confirm her role as a leading contributor to modern chemistry, where Experimental Methods not only support discovery but drive scientific evolution. Ultimately, her journey demonstrates how perseverance, creativity, and meticulous Experimental Methods shape impactful careers and contribute meaningfully to global scientific advancement.

Kamila Dus-Szachniewicz | Experimental Methods | Women Researcher Award

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Kamila Dus-Szachniewicz | Experimental Methods | Women Researcher Award

Ass. Prof. at Wrocław Medical University | Poland

Assoc. Prof. Dr. Kamila Dus-Szachniewicz has an extensive background in clinical and experimental pathology, with a strong focus on Experimental Methods in cancer research. Her career reflects a deep integration of Experimental Methods in proteomics, tumor microenvironment modeling, and innovative diagnostic approaches. She works at Wrocław Medical University, advancing Experimental Methods that combine optical tweezers technology and mass spectrometry for precision oncology. Her leadership in pioneering Experimental Methods has resulted in several patents and influential publications. This summary highlights her capacity to merge fundamental science with practical applications, pushing the boundaries of Experimental Methods in medical diagnostics, cancer cell interaction analysis, and therapeutic development within translational oncology.

Professional Profiles

Google Scholar Profile | ORCID Profile

Education 

Assoc. Prof. Dr. Kamila Dus-Szachniewicz has pursued academic excellence through a comprehensive education grounded in Experimental Methods and biological sciences. She earned her master’s in biology, specializing in genetics and microbiology, further shaping her foundational understanding of cellular systems. Her Ph.D. in Medical Sciences integrated Experimental Methods to analyze colorectal adenoma and carcinoma through proteomics. Later, she completed her Doctor of Medical Sciences (habilitation), employing Experimental Methods such as optical tweezers to assess lymphomas under diverse microenvironmental conditions. This educational journey reflects a consistent emphasis on Experimental Methods, providing the skills and theoretical grounding essential for innovation in modern cancer research and diagnostic tool development.

Experience 

Assoc. Prof. Dr. Kamila Dus-Szachniewicz’s professional experience is distinguished by her consistent application of Experimental Methods across multiple high-impact research areas. At Wrocław Medical University, she developed proteomic techniques for FFPE tissue analysis, enhancing cancer biomarker discovery through advanced Experimental Methods. She established and characterized three-dimensional lymphoma spheroid models, integrating Experimental Methods to simulate tumor microenvironments and improve translational relevance. Moreover, she applied optical tweezers-based Experimental Methods to study cell adhesion, develop hybrid spheroids, and support personalized oncology. Her role as a research project leader demonstrates her ability to design, implement, and manage sophisticated Experimental Methods to address pressing challenges in hematological malignancy diagnostics and therapeutic strategy development.

Research Interest 

Assoc. Prof. Dr. Kamila Dus-Szachniewicz’s research interests are deeply rooted in the innovative use of Experimental Methods to solve complex problems in oncology. She focuses on proteomic profiling of cancer progression, enabling precision diagnostics through optimized Experimental Methods. Her work includes constructing advanced tumor models to mimic lymphoma-microenvironment crosstalk, improving Experimental Methods for studying drug response and cell-cell interaction. Additionally, she explores the use of optical tweezers-based Experimental Methods to analyze mechanical and adhesive properties of cancer cells, linking physical forces with therapeutic outcomes. These research interests collectively illustrate her commitment to advancing Experimental Methods for more predictive, precise, and clinically relevant cancer research approaches.

Award and Honor

Assoc. Prof. Dr. Kamila Dus-Szachniewicz has been recognized for her outstanding contributions to science through several prestigious awards and honors emphasizing Experimental Methods in oncology. Her pioneering use of optical tweezers as part of Experimental Methods in hematological cancer research garnered institutional and national funding. The successful completion of competitive projects has elevated Experimental Methods as transformative tools in diagnostic innovation. Her contributions have also been acknowledged through grants promoting translational applications of Experimental Methods in cancer biology. These honors underscore her leadership and vision, reaffirming the importance of Experimental Methods in redefining how cellular interactions and therapeutic targets are identified and validated in modern medicine.

Research Skill

Assoc. Prof. Dr. Kamila Dus-Szachniewicz has developed a powerful set of research skills, all interconnected by her mastery of Experimental Methods. She has refined skills in proteomic analysis using mass spectrometry, a cornerstone of modern Experimental Methods for biomarker discovery. Her ability to design and manage complex cell culture systems, including hybrid lymphoma spheroids, highlights her proficiency in Experimental Methods modeling disease biology. Furthermore, her technical expertise in optical tweezers-based assays exemplifies how Experimental Methods can quantify mechanical properties of cancer cells. Collectively, her research skills demonstrate a profound capacity to implement and advance Experimental Methods that bridge molecular insights, cellular behavior, and therapeutic innovation in oncology.

Publication Top Notes 

Title: Extensive quantitative remodeling of the proteome between normal colon tissue and adenocarcinoma
Journal: Molecular Systems Biology
Authors: JR Wiśniewski, P Ostasiewicz, K Duś, DF Zielińska, F Gnad, M Mann
Citation: 274

Title: Proteomic workflow for analysis of archival formalin‐fixed and paraffin‐embedded clinical samples to a depth of 10 000 proteins
Journal: PROTEOMICS–Clinical Applications
Authors: JR Wiśniewski, K Duś, M Mann
Citation: 174

Title: Absolute proteome analysis of colorectal mucosa, adenoma, and cancer reveals drastic changes in fatty acid metabolism and plasma membrane transporters
Journal: Journal of Proteome Research
Authors: JR Wiśniewski, K Duś-Szachniewicz, P Ostasiewicz, P Ziółkowski, ...
Citation: 89

Title: Toward controlled photothermal treatment of single cell: optically induced heating and remote temperature monitoring in vitro through double wavelength optical tweezers
Journal: ACS Photonics
Authors: S Drobczyński, K Prorok, K Tamarov, K Duś-Szachniewicz, VP Lehto, ...
Citation: 43

Title: Physiological hypoxia (physioxia) impairs the early adhesion of single lymphoma cell to marrow stromal cell and extracellular matrix. Optical tweezers study
Journal: International Journal of Molecular Sciences
Authors: K Duś-Szachniewicz, S Drobczyński, P Ziółkowski, P Kołodziej, ...
Citation: 28

Title: Pattern of melanotransferrin expression in human colorectal tissues: an immunohistochemical study on potential clinical application
Journal: Anticancer Research
Authors: K Duś-Szachniewicz, P Ostasiewicz, M Woźniak, P Kołodziej, ...
Citation: 24

Title: Real-time force measurement in double wavelength optical tweezers
Journal: Journal of the Optical Society of America B
Authors: S Drobczyński, K Duś-szachniewicz
Citation: 19

Title: Quantitative analysis of gene expression in fixed colorectal carcinoma samples as a method for biomarker validation
Journal: Molecular Medicine Reports
Authors: B Ostasiewicz, P Ostasiewicz, K Duś-Szachniewicz, K Ostasiewicz, ...
Citation: 18

Title: Protein tyrosine phosphatase receptor R and Z1 expression as independent prognostic indicators in oral squamous cell carcinoma
Journal: Head & Neck
Authors: K Duś‐Szachniewicz, M Woźniak, K Nelke, E Gamian, H Gerber, ...
Citation: 18

Title: Insulin-like growth factor-2 is induced following 5-aminolevulinic acid-mediated photodynamic therapy in SW620 human colon cancer cell line
Journal: International Journal of Molecular Sciences
Authors: M Woźniak, K Duś-Szachniewicz, P Ziółkowski
Citation: 18

Title: Development and characterization of 3D hybrid spheroids for the investigation of the crosstalk between B-cell non-Hodgkin lymphomas and mesenchymal stromal cells
Journal: OncoTargets and Therapy
Authors: K Duś-Szachniewicz, K Gdesz-Birula, G Rymkiewicz
Citation: 16

Title: Proteomic-based analysis of hypoxia-and physioxia-responsive proteins and pathways in diffuse large B-cell lymphoma
Journal: Cells
Authors: K Duś-Szachniewicz, K Gdesz-Birula, K Zduniak, JR Wiśniewski
Citation: 15

Title: The assessment of the combined treatment of 5-ALA mediated photodynamic therapy and thalidomide on 4T1 breast carcinoma and 2H11 endothelial cell line
Journal: Molecules
Authors: K Zduniak, K Gdesz-Birula, M Woźniak, K Duś-Szachniewicz, ...
Citation: 14

Title: Immunohistochemical study of nuclear ubiquitous casein and cyclin-dependent kinase substrate 1 in invasive breast carcinoma of no special type
Journal: Experimental and Therapeutic Medicine
Authors: K Symonowicz, K Duś-Szachniewicz, M Woźniak, M Murawski, ...
Citation: 14

Title: Differentiation of single lymphoma primary cells and normal B-cells based on their adhesion to mesenchymal stromal cells in optical tweezers
Journal: Scientific Reports
Authors: K Duś-Szachniewicz, S Drobczyński, M Woźniak, K Zduniak, ...
Citation: 13

Title: Vacata‐and divacataporphyrin: New photosensitizers for application in photodynamic therapy—an in vitro study
Journal: Lasers in Surgery and Medicine
Authors: M Klyta, P Ostasiewicz, K Jurczyszyn, K Duś, L Latos‐Grażyński, ...
Citation: 13

Title: Spectral analysis by a video camera in a holographic optical tweezers setup
Journal: Optica Applicata
Authors: S Drobczynski, K Dus-Szachniewicz, K Symonowicz, D Glogocka
Citation: 10

Title: Formation of lymphoma hybrid spheroids and drug testing in real time with the use of fluorescence optical tweezers
Journal: Cells
Authors: K Duś-Szachniewicz, K Gdesz-Birula, E Nowosielska, P Ziółkowski, ...
Citation: 9

Title: Immunocytochemical studies on the nuclear ubiquitous casein and cyclin-dependent kinases substrate following 5-aminolevulinicacid-mediated photodynamic therapy on MCF-7 cells
Journal: Photodiagnosis and Photodynamic Therapy
Authors: K Hotowy, M Woźniak, K Duś, E Czapińska, B Osiecka, ...
Citation: 8

Title: Large-scale proteomic analysis of follicular lymphoma reveals extensive remodeling of cell adhesion pathway and identifies hub proteins related to the lymphomagenesis
Journal: Cancers
Authors: K Duś-Szachniewicz, G Rymkiewicz, AK Agrawal, P Kołodziej, ...
Citation: 7

Conclusion

Assoc. Prof. Dr. Kamila Dus-Szachniewicz represents a leading figure in modern translational oncology, driven by her expertise in Experimental Methods. Her educational background, professional achievements, research leadership, and impactful publications converge to form a profile that illustrates the transformative power of Experimental Methods in advancing medical science. Through proteomics, tumor modeling, and optical manipulation technologies, she has demonstrated how Experimental Methods can bridge the gap between fundamental biology and clinical applications. This conclusion underscores her vital role in shaping future diagnostic and therapeutic strategies, inspiring continued development of Experimental Methods that will refine and personalize cancer care for improved patient outcomes.

Dr. Yuanhang Yang | Experimental Methods | Young Scientist Award

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Dr. Yuanhang Yang | Experimental Methods | Young Scientist Award

Research fellow at Nanyang Technological University, Singapore

Dr. Yuanhang Yang has developed a strong academic and research profile in engineering, with special focus on flexible devices, soft materials, and innovative fabrication technologies. His work consistently integrates Experimental Methods into the design and analysis of advanced systems. By applying Experimental Methods in multiple domains, he has contributed significantly to the fields of smart healthcare, wearable technologies, and materials science. Through his publications and patents, Dr. Yang demonstrates leadership in research innovation, particularly with Experimental Methods that promote practical and interdisciplinary solutions. His summary reflects a career centered on Experimental Methods as the foundation of modern engineering, ensuring impactful progress in intelligent devices and flexible systems that serve global technological advancements.

Professional Profile

Google Scholar Profile 

Education 

Dr. Yuanhang Yang’s education highlights his strong foundation in mechanical and nuclear engineering, supported by advanced studies in mechanical engineering and materials science. His academic background showcases continuous learning, where Experimental Methods have played a crucial role in strengthening his expertise. Through rigorous research training, he applied Experimental Methods in the study of soft materials, corrosion protection, and flexible electronics. Each educational milestone provided opportunities to refine Experimental Methods as a core approach to discovery. His education not only provided theoretical knowledge but also extensive hands-on practice with Experimental Methods, ensuring that his research outcomes are grounded in scientific precision and innovation. This foundation empowers him to contribute meaningfully across interdisciplinary fields.

Experience 

Dr. Yuanhang Yang has held multiple professional roles, including research fellow, research assistant, and teaching assistant, which allowed him to integrate Experimental Methods into both academic and industrial projects. In every position, he prioritized Experimental Methods to enhance the design, development, and testing of flexible devices and advanced materials. His professional journey reflects a dedication to Experimental Methods as tools for solving complex challenges in aerospace, nuclear, and biomedical engineering. Each role provided unique opportunities to refine and expand the application of Experimental Methods, allowing him to lead and contribute to projects that bridge theory with practice. His experience emphasizes adaptability and excellence driven by Experimental Methods.

Research Interest 

Dr. Yuanhang Yang’s research interests center on flexible devices, programmable systems, and smart materials, all explored through Experimental Methods. His focus includes wearable technologies, biomedical applications, and interdisciplinary solutions powered by advanced fabrication. Experimental Methods form the backbone of his research strategy, guiding the exploration of soft robotics, shape-morphing structures, and intelligent healthcare devices. By consistently relying on Experimental Methods, he ensures that his research findings are validated, reproducible, and practically relevant. Dr. Yang’s research interests highlight the essential role of Experimental Methods in bridging material science, engineering, and healthcare technologies, contributing to innovations that respond to pressing scientific and societal needs worldwide.

Award and Honor

Dr. Yuanhang Yang has received multiple honors and awards that underline his dedication to research excellence through Experimental Methods. He earned recognition such as dissertation awards, innovation competition awards, and professional engineering certifications. These accolades affirm his strong use of Experimental Methods in tackling significant engineering problems. Awards for academic excellence, innovation design, and contributions to student communities all demonstrate his well-rounded achievements. His recognition in international competitions reflects the global relevance of his Experimental Methods approach. Each award highlights his capacity to integrate Experimental Methods into practical outcomes, making him a distinguished researcher whose work is celebrated for both academic and applied impact.

Research Skill

Dr. Yuanhang Yang possesses advanced research skills deeply rooted in the effective use of Experimental Methods. His skills include designing, fabricating, and analyzing flexible electronic systems, utilizing Experimental Methods for precise testing and validation. He demonstrates expertise in advanced printing, 3D fabrication, and material characterization, all reinforced by Experimental Methods. These skills allow him to bridge fundamental science with technological innovation. Whether in laboratory settings or collaborative projects, his reliance on Experimental Methods ensures accuracy, reproducibility, and innovation. Dr. Yang’s skills extend to interdisciplinary integration, where Experimental Methods help unify diverse fields like biomedical engineering, smart healthcare, and materials science. His research skillset is defined by Experimental Methods as a cornerstone.

Publication Top Notes 

Title: Advances in constructing silver nanowire-based conductive pathways for flexible and stretchable electronics
Authors: Y Yang, S Duan, H Zhao
Journal: Nanoscale

Title: Silver nanowire-based stretchable strain sensors with hierarchical wrinkled structures
Authors: Y Yang, S Duan, W Xiao, H Zhao
Journal: Sensors and Actuators A: Physical

Title: Water-induced polymer swelling and its application in soft electronics
Authors: Y Yang, H Zhao
Journal: Applied Surface Science

Title: Influence of MAO treatment on the galvanic corrosion between aluminum alloy and 316L steel
Authors: Y Yang, Y Gu, L Zhang, X Jiao, J Che
Journal: Journal of Materials Engineering and Performance

Title: Analysis on corrosion of aluminum-based micro-arc oxidation coating
Authors: Y Yang, G Feng, Y Gu, J Zhao, J Liang
Journal: Anti-Corrosion Methods and Materials

Title: 3D printing of antibacterial polymer devices based on nitric oxide release from embedded S-nitrosothiol crystals
Authors: L Wuwei, Y Yuanhang, CJ Ehrhardt, N Lewinski, D Gascoyne, ...
Journal: ACS Applied Bio Materials

Title: Highly conductive silicone elastomers via environment‐friendly swelling and in situ synthesis of silver nanoparticles
Authors: Y Yang, S Duan, H Zhao
Journal: Advanced Materials Interfaces

Title: Bio-inspired facile strategy for programmable osmosis-driven shape-morphing elastomer composite structures
Authors: Y Yang, Y Wang, M Lin, M Liu, C Huang
Journal: Materials Horizons

Title: Advanced printing transfer of assembled silver nanowire network into elastomer for constructing stretchable conductors
Authors: Y Yang, W Li, S Sreenivasan Narayanan, X Wang, H Zhao
Journal: Advanced Engineering Materials

Title: Analysis on corrosion failure of aluminum alloy drill pipe for scientific ultra-deep well drilling
Authors: J Liang, YH Gu, W Yue, JH Sun, JX Liu, YH Yang
Journal: Exploration Engineering (Rock & Soil Drilling and Tunneling)

Title: Effects of micro-arc oxidation treatment on galvanic corrosion behavior between aluminum alloy drill pipe and steel joints
Authors: L Jian, Guo Yan-hong, Y Yuan-hang
Journal: Materials Protection

Title: A proposal for modified galvanic corrosion model: Investigating effects of micro-arc oxidation on Al alloy
Authors: Y Yang, Y Gu, J Liang, W Yue
Journal: Surface Review and Letters

Title: Comparisons of air and water oxidation on the passive properties of chromium
Authors: Y Yang, F Zhao, Y Ling, X Yang, Y Gu, Z Zhang
Journal: Journal of Materials Engineering and Performance

Title: One-pot fabrication of bio-inspired shape-morphing bilayer structures
Authors: Y Yang, B Cao, Y Tang, C Huang
Journal: Chemical Engineering Journal

Conclusion

Dr. Yuanhang Yang’s career reflects a consistent commitment to using Experimental Methods as the foundation of his academic and professional journey. His education, professional experience, and research achievements all demonstrate the central role of Experimental Methods in producing reliable, innovative, and impactful outcomes. From publications to patents, every contribution embodies his reliance on Experimental Methods as tools for excellence. His awards and honors further highlight the recognition gained through the consistent application of Experimental Methods. In conclusion, Dr. Yang stands as a distinguished researcher whose success stems from his mastery and advancement of Experimental Methods across interdisciplinary scientific domains.