Dr. Shoaib Nazir | Nanotechnology | Excellence in Research

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Dr. Shoaib Nazir | Nanotechnology | Excellence in Research

Dr. Shoaib Nazir , Nanotechnology , Postdoctoral Researcher at Shenzhen University, China

🎓 Shoaib Nazir is a passionate physicist and materials researcher from Pakistan, currently pursuing his Ph.D. at Shaanxi Normal University, Xi’an, China. With expertise in nanomaterials synthesis and characterization, Shoaib’s academic journey reflects a strong dedication to cutting-edge research in materials science. Before moving to China, he earned his M.Phil. in Physics from Riphah International University and a BS (Hons.) from COMSATS, Lahore. Beyond his academic pursuits, he has significantly contributed to education as a senior lecturer and department head in multiple institutions across Pakistan, shaping future scientists with enthusiasm and leadership. His research primarily focuses on nanotechnology, magnetic materials, and materials for electronics and photonics, resulting in several reputable publications. Shoaib is actively engaged on academic platforms like ResearchGate and Google Scholar and stays connected globally via social media and professional networks. His multilingual abilities and cultural adaptability further enrich his academic and professional endeavors.

Professional Profile : 

Google Scholar 

Summary of Suitability for Award:

Shoaib Nazir demonstrates strong potential for recognition under an “Excellence in Research” award. He has built a focused research profile in nanomaterials and material sciences, publishing multiple papers in reputable journals such as Ceramics International and the Arabian Journal of Chemistry. His Ph.D. research in synthesizing and characterizing pure and doped nanomaterials aligns well with high-impact, cutting-edge fields relevant to electronics, photonics, and magnetic applications, contributing valuable insights to advanced material development. His ability to handle complex experimental techniques and multidisciplinary topics like structural, optical, and magnetic characterization underlines his technical proficiency and research depth. Moreover, his proactive academic engagement, including international study and multilingual skills, signifies adaptability and global research vision. Shoaib Nazir is a suitable candidate for an “Excellence in Research” award, particularly in the early-career researcher or emerging scientist categories. His specialized expertise in nanomaterials synthesis and characterization, coupled with quality publications and an international academic background, demonstrates clear merit and potential for significant contributions to materials science and physics. With further research output and collaborations, Shoaib is well-positioned to achieve even greater recognition in his field.

🎓Education:

Shoaib Nazir embarked on his academic journey in physics with a BS (Hons.) degree from COMSATS Institute of Information & Technology Lahore, Pakistan (2011–2015), where he completed a final-year report on space weather events and Earth’s magnetosphere. He then pursued his Master’s (M.Phil.) in Physics at Riphah International University, Islamabad, Pakistan (2015–2017), focusing his dissertation on the synthesis and characterization of hexaferrites. Passionate about expanding his horizons, Shoaib moved to China for his Ph.D. in Physics (2020–2024) at Shaanxi Normal University, Xi’an, where he specializes in synthesizing and characterizing pure and doped nanomaterials. In addition, he studied the Chinese language (HSK 4) from 2019–2020 to facilitate his integration into the academic environment in China. His educational path reflects a strong foundation in physics and a keen focus on materials science, enabling him to bridge theoretical insights with practical applications in nanotechnology.

🏱Work Experience:

Shoaib Nazir boasts diverse professional experience as an educator and academic leader. He served from 2017 to 2022 as the Head of the Physics Department and Senior Lecturer at Punjab Group of Colleges, P.D. Khan Campus, Jhelum, where he led curriculum planning, teaching, and extracurricular initiatives. Prior to that, he worked at Government Degree College CSS, Chakwal (2016–2017), as a Senior Lecturer and Head of the Science Committee, overseeing both academic and student engagement activities. From 2015 to 2016, he was a Physics Lecturer at Govt. Albiruni Degree College, P.D. Khan, Jhelum, where he handled teaching and administrative responsibilities. Earlier in his career, he taught physics and mathematics at The Cambridge Group of Education, Lahore (2013–2015), as a Senior Science Teacher. Throughout his teaching journey, Shoaib has honed his skills in delivering complex scientific concepts with clarity, fostering curiosity and academic excellence among his students.

🏅Awards: 

While specific formal awards are not listed in Shoaib Nazir’s CV, his career reflects significant achievements and honors through his progressive roles and academic contributions. Serving as Head of Department and Senior Lecturer in multiple prestigious colleges in Pakistan highlights his professional recognition and trust as a leader and educator. His successful admission and ongoing pursuit of a Ph.D. in Physics at a respected Chinese university underscore his academic excellence and competitiveness on the international stage. Additionally, his ability to publish in high-impact journals like Ceramics International and Arabian Journal of Chemistry demonstrates scholarly merit. Shoaib’s active engagement in extracurricular activities and leadership roles throughout his career points to his multifaceted contributions and the respect he commands in academic circles. His linguistic achievement in completing HSK 4 in Chinese further indicates his dedication and adaptability, positioning him as an accomplished scholar and educator with global aspirations.

🔬Research Focus:

Shoaib Nazir’s research lies at the fascinating intersection of nanotechnology and materials science, focusing on synthesizing and characterizing advanced materials for electronics and photonics. His interests encompass the development of nanoparticles, magnetic materials such as ferrites, and materials tailored for electronic device applications. He delves into studying structural, magnetic, optical, and electrical properties of both pure and doped nanomaterials to explore potential technological applications. By doping materials like ZnO nanoparticles with transition metals, Shoaib investigates ways to enhance material performance for electronic devices. His work contributes to understanding magneto-optical phenomena, crucial for photonic and magnetic storage technologies. His Ph.D. research centers on pure and doped nanomaterials synthesis, a field poised to revolutionize next-generation electronic components, sensors, and energy applications. With publications in respected journals, Shoaib’s research aims to bridge the gap between fundamental physics and practical innovations, driving advancements in nanotechnology and modern material engineering.

Publication Top Notes:

1. Modification in structural, optical, morphological, and electrical properties of zinc oxide (ZnO) nanoparticles (NPs) by metal (Ni, Co) dopants for electronic device applications
Citations: 104

2. Structural, magnetic, and electrical evaluations of rare earth Gd3+ doped in mixed Co–Mn spinel ferrite nanoparticles
Citations: 57

3.Magneto-optical properties and physical characteristics of M-type hexagonal ferrite (Ba₁₋ₓCaₓFe₁₁.₄Al₀.₆O₁₉) nanoparticles (NPs)
Citations: 46

4.Green synthesis of AgNPs from leaves extract of Saliva Sclarea, their characterization, antibacterial activity, and catalytic reduction ability
Citations: 45

5.Metal-based nanoparticles: basics, types, fabrications and their electronic applications
Citations: 43

6. Techno-economic and environmental perspectives of solar cell technologies: a comprehensive review
Citations: 30

7.Modification of physicochemical and electrical characteristics of lead sulfide (PbS) nanoparticles (NPs) by manganese (Mn) doping for electronic device and applications
Citations: 13

8. A comparative study of structural, vibrational mode, optical and electrical properties of pure nickel selenide (NiSe) and Ce-doped NiSe nanoparticles for electronic device applications
Citations: 13

9. Improvements in the physicochemical and electrical characteristics of BaO nanoparticles by Cu doping for electronic device applications
Citations: 12

10. Synthesis and characterization of Fe-substituting BaO nanoparticles by sol-gel method
Citations: 11

 

Dr. Abdul Abdul | Nanotechnology | Best Researcher Award

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Dr. Abdul Abdul | Nanotechnology | Best Researcher Award

Dr. Abdul Abdul , Nanotechnology , Associate Prof at Quanzhou University of Information Engineering, China

Dr. M. Abdul is an experimental physicist specializing in quantum many-body systems using ultracold atoms and quantum gases. He earned his Ph.D. from the University of Science and Technology of China, focusing on Boson Sampling schemes in optical lattices. Dr. Abdul has worked as an Assistant Professor at Sichuan University and is currently a full-time researcher at the University of Electronic Science and Technology of China. His research spans quantum optics, nonlinear optics, ultracold quantum gases, and high-resolution imaging. Dr. Abdul is highly skilled in developing ultrahigh vacuum systems, homemade lasers, and advanced imaging setups. With a resilient, positive, and hardworking personality, he has contributed to multiple research projects, applied for two patents, and published extensively in top journals. Fluent in English and beginner-level Chinese, Dr. Abdul embodies a cooperative spirit in scientific innovation and collaboration.

Professional Profile : 

Orcid

Scopus 

Summary of Suitability for Award:

Dr. M. Abdul is a dynamic and accomplished experimental physicist with a strong academic and research background in quantum optics, ultracold atomic systems, quantum simulation, and nonlinear optics. His research interests lie at the cutting edge of modern quantum physics, particularly in Boson sampling, high-resolution optical lattices, and superlattice-based quantum simulations. His career reflects a consistent and impactful contribution to both theoretical modeling and experimental implementation in advanced photonics and quantum technologies. Dr. M. Abdul is a highly deserving candidate for the “Best Researcher Award”. His research profile is marked by academic rigor, technical innovation, and interdisciplinary reach. With an impressive record of publications, international collaborations, and pioneering work in quantum systems and optics, he stands out as a leader among early- to mid-career researchers. His contributions not only advance fundamental science but also open new avenues for applications in quantum technologies and material science.

🎓Education:

Dr. M. Abdul pursued his Ph.D. in Physics at the University of Science and Technology of China (2014–2018), focusing on Boson Sampling with ultracold atoms. He completed his M.Phil. in Electronics from Quaid-I-Azam University Islamabad (2009–2011), achieving top national ranking, and earned an M.Sc. in Physics specializing in Electronics from Bahauddin Zakariya University, Multan (2006–2008). His undergraduate B.Sc. degree in Physics and Mathematics was also obtained from Bahauddin Zakariya University (2003–2006). Currently, he is serving as a full-time researcher at the University of Electronic Science and Technology of China (2022–2025). His academic journey reflects a consistent focus on quantum physics, electronic systems, and ultracold atomic research. He has also undertaken specialized training in laser systems, optical lattices, and computational physics tools, equipping him with deep experimental and theoretical proficiencies in modern quantum technologies.

🏱Work Experience:

Dr. M. Abdul has held several prestigious academic and teaching positions. From December 2018 to March 2022, he served as an Assistant Professor at Sichuan University, College of Physics, where he worked on optical lattices and ultracold atoms. Since May 2022, he has been a full-time researcher at the University of Electronic Science and Technology of China. Earlier in his career, he taught Physics and Mathematics at Down High School, Punjab Group of Colleges, and St. Mary College in Rawalpindi, developing a strong foundation in educational leadership and student mentorship. He also contributed to various national-level research projects in Pakistan, including studies on nonlinear atomic dynamics and nano-devices. His diverse professional experience combines experimental physics research, teaching, and development of advanced laboratory setups like vacuum systems, lasers, and imaging systems, establishing him as a multifaceted expert in quantum technologies.

🏅Awards: 

Dr. M. Abdul has achieved significant recognition throughout his academic career. He secured the first rank in his M.Phil. program at Quaid-I-Azam University, Islamabad. During his Ph.D. tenure, he contributed to several funded national and international research projects, such as those supported by the National Higher Education Commission of Pakistan and the National Science Foundation of China (NSFC). He has applied for two patents related to laser and optical technologies. His research presentations at major international conferences, including QCMC 2014 (China) and CHAOS2018, reflect his growing influence in quantum physics and nonlinear dynamics communities. Invitations to submit in top-tier journals such as Applied Physics Reviews and contributions to organizing international conferences on nanoscience further mark his career. His awards and project leadership roles highlight his excellence, innovation, and dedication to advancing the field of quantum optics and ultracold atom systems.

🔬Research Focus:

Dr. M. Abdul’s research primarily centers on quantum simulation, quantum optics, ultracold quantum gases, and many-body quantum systems. His doctoral work explored Boson Sampling schemes using ultracold atoms in optical lattices. He has since expanded his expertise into high-resolution imaging using superlattices and nonlinear optics with a focus on cavity-based laser systems. His work involves developing ultrahigh vacuum systems, laser stabilization circuits, and DMD-based imaging technologies. He is also engaged in first-principles studies of optical, electronic, and thermoelectric properties of novel perovskite materials. Dr. Abdul’s projects aim to realize quantum metamaterials and quantum memory devices, critical for future quantum technologies. His current focus includes creating spatially entangled bosonic systems, manipulating surface plasmon polaritons, and engineering ultracold atoms for Hong-Ou-Mandel interference experiments. His interdisciplinary approach bridges theoretical modeling with advanced experimental setups, contributing to the next-generation quantum simulation platforms.

Publication Top Notes:

1. Synergistic Improvement of OER/HER Electrocatalytic Performance of Cu₂Te via the Introduction of Zr for Water Electrolysis

2. Facile Synthesis of Co₃Te₄–Fe₃C for Efficient Overall Water-Splitting in an Alkaline Medium

3. Manipulation of Surface Plasmon Polariton Fields Excitation at Quantum-Size Slit in a Dielectric and Graphene Interface

4. Exploring the Properties of Zr₂CO₂/GaS van der Waals Heterostructures for Optoelectronic Applications

5. Effects of Thermal Fluctuation When an Optical Cavity Possesses Neutral Atoms and a Two-Mode Laser System

6. Synchronized Attractors and Phase Entrained with Cavity Loss of the Coupled Laser’s Map

 

 

Mr. Muhammad Ali | Crystalline defects | Best Researcher Award

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Mr. Muhammad Ali | Crystalline defects | Best Researcher Award

Mr. Muhammad Ali | Crystalline defects | PhD candidate at IMR, Chinese Academy of Sciences, China

Muhammad Ali is a dedicated PhD candidate at the Institute of Metal Research, Chinese Academy of Sciences, Shenyang. With a robust academic background in metallurgical and materials engineering, he specializes in physical metallurgy and advanced characterisation techniques. His research explores the process-structure-property relationship of high-performance alloys like Zr, Ti, and Mg alloys. His PhD work has contributed significantly to the development of modified Zircaloys through in-depth study of crystallography of second phase precipitates using advanced transmission electron microscopy. He has also worked on additively manufactured Mo-47.5Re and W-3Re alloys, optimizing their microstructures and mechanical behaviors. Muhammad Ali has over 71 publications in reputed journals, with a growing citation record. His research contributes to innovation in structural materials used in critical applications, including aerospace, biomedical devices, and nuclear reactor components. He is committed to advancing materials science through collaborative, high-impact research.

Professional Profile :         

Orcid

Scopus 

Summary of Suitability for Award:

Muhammad Ali is an outstanding early-career researcher in materials science and metallurgy, with specialized expertise in additive manufacturing, intermetallics, and physical metallurgy. He has conducted significant original research on advanced alloys like Mo-Re, W-Re, and modified Zircaloy-4, contributing to critical advancements in nuclear materials, structural alloys, and crystallography of second-phase precipitates.Furthermore, his contribution to understanding crystalline defects, texture evolution, and occupational order-disorder phenomena in intermetallics reflects deep analytical skill and originality—an essential quality of a top researcher.Given his strong research record, specialized expertise, and direct contributions to industrially relevant materials, Muhammad Ali is highly suitable for the “Best Researcher Award.” His work demonstrates innovation, academic excellence, and interdisciplinary relevance, making him a deserving candidate for recognition on both national and international platforms.

🎓Education:

Muhammad Ali has pursued a comprehensive academic journey in Metallurgical and Materials Engineering. He completed his Bachelor’s and Master’s degrees in the field, gaining solid foundational knowledge in physical metallurgy, thermomechanical treatments, and alloy design. Currently, he is enrolled as a PhD candidate at the prestigious Institute of Metal Research, Chinese Academy of Sciences, Shenyang. His doctoral work focuses on crystallographic characterization of second phase precipitates in Zircaloy-4 and its modified variants. Utilizing state-of-the-art techniques like transmission electron microscopy (TEM), he investigates orientation relationships, interfacial structures, and defect mechanisms in complex Zr intermetallics. His academic training has emphasized advanced characterization methods, allowing him to explore atomic-scale features critical to alloy performance. This robust education has equipped him with a unique skill set to tackle modern materials challenges and contribute to both theoretical and applied materials science, especially in high-performance structural alloys.

🏱Work Experience:

Muhammad Ali’s research journey reflects a solid combination of academic rigor and applied science. As a PhD researcher at the Institute of Metal Research, Chinese Academy of Sciences, he has worked on high-impact projects involving cutting-edge materials. His core expertise lies in investigating the structure-property relationships in advanced alloys. He has conducted detailed microstructural and mechanical investigations on Ti-based alloys like Ti-6Al-4V and Ti-7411, and explored plastic behavior through EBSD and TEM techniques. In industrial collaboration projects, he worked on electron beam melted Mo-47.5Re and W-3Re alloys, optimizing processing parameters and analyzing mechanical behavior post-Rockwell indentation. Additionally, he contributed to nuclear materials research through the crystallographic study of second phases in modified Zircaloy-4. His multidisciplinary approach to materials characterization spans XRD, SEM, EBSD, and TEM, giving him a well-rounded understanding of metallurgy. These experiences make him well-positioned to drive innovation in structural alloy development.

🏅Awards: 

While Muhammad Ali has not listed formal awards in this profile, his contributions to scientific research are noteworthy and impactful. He has published over 71 research articles in reputed peer-reviewed journals, a significant accomplishment for a doctoral researcher. His citation index of 14 reflects growing recognition within the scientific community. His active participation in multiple collaborative research projects, particularly those involving additive manufacturing of Mo- and W-Re alloys, demonstrates his relevance to both academia and industry. Furthermore, his work in modifying Zircaloy-4 to enhance irradiation performance is directly linked to the energy sector, particularly nuclear reactor optimization, making his research of national and international importance. Muhammad Ali’s dedication to advancing materials science is also evident in his continued collaboration with industry and academia. As he continues to contribute to critical research in physical metallurgy and intermetallic behavior, he remains a promising candidate for future awards and research honors.

🔬Research Focus:

Muhammad Ali’s research is centered on materials science with a deep focus on physical metallurgy, crystallography, and characterization of metallic alloys. His doctoral thesis emphasizes the study of second-phase precipitates in Zircaloy-4 and its modified forms, aiming to enhance performance in nuclear environments. His work explores the orientation relationships, interfacial structures, and crystalline defects within intermetallic compounds using advanced transmission electron microscopy techniques. In parallel, he has worked on Ti-based alloys, investigating microstructural evolution under various thermomechanical treatments and their implications on mechanical behavior and texture. Moreover, Muhammad has contributed to research on additively manufactured Mo-47.5Re and W-3Re alloys, focusing on processing techniques like electron beam melting and post-deformation microstructural analysis. His broader research seeks to establish strong process-structure-property correlations to innovate in the development of materials for aerospace, biomedical, and energy sectors. His interdisciplinary approach bridges fundamental science and real-world application.

Publication Top Notes:

“Selection of {10-12} twin variants during uniaxial compression in pure hafnium”

“Uncovering the crystallography and formation mechanism of nanoscale clusters in Sb-rich SPPs of a p-type (Bi, Sb)₂Te₃ alloy”

“Increasing Atomic Electron Cloud Density Leads to Formation of Body Centered Cubic (BCC) Gold”

“10-12} <1011> Twinning Transfer Behavior in Compressed High-Purity Hafnium”​

“Stress-Induced Intersecting Stacking Faults and Shear Antiphase Boundary in Zr5Ge4 Second Phase Precipitate Embedded in Ge-Modified Zircaloy-4”

 

 

Dr. Ali Yazdani | Nanomaterials | Best Researcher Award

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Dr. Ali Yazdani | Nanomaterials | Best Researcher Award

Dr. Ali Yazdani, School of Electrical and Computer Engineering, College of Engineering, University of Tehran, Iran

Ali Yazdani is a biomedical engineer affiliated with the School of Electrical and Computer Engineering, College of Engineering, University of Tehran, Iran. His research primarily focuses on early cancer detection, MRI contrast agents, and bioprinting. He has contributed to groundbreaking projects in image processing for medical applications, sperm isolation using microfluidics, and tissue engineering. As the Managing Director of Omid-Afarinan Mohandesi Ayandeh Co., he plays a pivotal role in developing 3D bioprinters. He has also collaborated with Parsis Co. to develop a smart surgical software and worked at the Royan Institute to model stem cell injection timing for Lupus treatment. With three publications in indexed journals, seven research projects, ten industry projects, and one patent, his work has significantly advanced the field of biomedical engineering. His contributions to MRI contrast agent synthesis from herbal sources highlight his innovative approach in medical imaging.

Professional Profile:

Google Scholar

Summary of Suitability for Award:

Ali Yazdani is an outstanding biomedical engineer with expertise in early cancer detection, MRI contrast agents, and bioprinting. His strong academic background from the University of Tehran and interdisciplinary research contributions make him a highly qualified candidate for the Best Researcher Award. He has seven completed/ongoing research projects, ten industry collaborations, one patent, and three journal publications in SCI/Scopus-indexed journals. His work on herbal-based MRI contrast agents, AI-driven surgical software, and 3D bioprinting has made significant contributions to biomedical imaging, regenerative medicine, and personalized healthcare. His leadership as Managing Director of Omid-Afarinan Mohandesi Ayandeh Co. further highlights his innovative impact. Given his exceptional research output, innovation in medical imaging, and impactful industry collaborations, Ali Yazdani is a strong contender for the “Best Researcher Award.”

🎓Education:

Ali Yazdani pursued Bachelor’s, Master’s, and Ph.D. degrees in Biomedical Engineering at the University of Tehran. He was part of the Electrical and Computer Engineering faculty, where he specialized in mathematical modeling of autoimmune diseases and imaging techniques for early cancer detection. His research during his doctoral studies was focused on alternative sources for MRI contrast agents, where he proposed an herbal-based approach to enhance MRI imaging quality. His academic journey was enriched with hands-on laboratory experiments, validating the efficiency of herbal-based MRI contrast agents. Throughout his education, he worked on interdisciplinary projects, combining engineering, medical sciences, and biotechnology to address critical challenges in medical imaging and diagnostics. His expertise in bioprinting, medical imaging, and stem cell research has been instrumental in his continued contributions to biomedical engineering.

🏱Work Experience:

Ali Yazdani has extensive experience in biomedical research and innovation. He is currently affiliated with the University of Tehran, where he has contributed to seven research projects and ten industry-sponsored projects. As the Managing Director of Omid-Afarinan Mohandesi Ayandeh Co., he is actively involved in 3D bioprinting technology. His collaboration with Parsis Co. led to the development of an AI-driven surgical guidance software. At the Royan Institute, he played a key role in a system identification project, modeling stem cell injection timing for Lupus patients. His expertise extends to medical image processing, tissue engineering, and regenerative medicine. His consulting work has supported multiple biomedical startups and research groups. With hands-on experience in MRI contrast agent synthesis, bioprinting, and stem cell research, he has significantly contributed to healthcare innovations, making biomedical diagnostics more accessible and efficient.

🏅Awards: 

Ali Yazdani has been recognized for his contributions to biomedical engineering and innovation. His research on herbal-based MRI contrast agents earned him recognition at international medical imaging conferences. As the Managing Director of Omid-Afarinan Mohandesi Ayandeh Co., he received industry appreciation for developing 3D bioprinting technology. His work on AI-driven surgical guidance software at Parsis Co. was acknowledged as a pioneering advancement in smart surgery. His stem cell research at Royan Institute was highly regarded in the regenerative medicine field. He has also received accolades for his industry collaborations, having led ten consultancy projects. His patent on organic MRI contrast agents showcases his innovative contributions to non-invasive diagnostics. With a strong impact on medical imaging, bioprinting, and regenerative medicine, his achievements have positioned him as a leading researcher in the field of biomedical engineering.

🔬Research Focus:

Ali Yazdani’s research spans across early cancer detection, MRI contrast agents, and bioprinting. His groundbreaking work in mathematical modeling of autoimmune diseases has contributed to better understanding of disease progression. His research on MRI contrast agents aims to replace synthetic agents with herbal-based alternatives, improving biocompatibility and reducing toxicity. His innovations in bioprinting technology focus on the synthesis of viable tissues for regenerative medicine. His image processing research includes X-marker detection for surgical tools and sperm isolation using microfluidics. His stem cell differentiation research utilizes periodic pulses to enhance cardiac cell regeneration. His contributions to ultrasonic and UV-based dormancy breaking of special beads have potential applications in biotechnology and medicine. His interdisciplinary approach—blending engineering, medical imaging, and regenerative medicine—makes his research highly impactful in healthcare technology and diagnostics.

Publication Top Notes:

A biological and a mathematical model of SLE treated by mesenchymal stem cells covering all the stages of the disease

Authors: A. Yazdani, F. Bahrami, A. Pourgholaminejad, R. Moghadasali

Journal: Theory in Biosciences

Volume: 142 (2), 167-179

Citations: 4

Year: 2023

Sub-pixel X-marker detection by Hough transform

Authors: A. Yazdani, H. Aalizadeh, F. Karimi, S. Solouki, H. Soltanian-Zadeh

Conference: 2018 25th National and 3rd International Iranian Conference on Biomedical 


Citations: 3

Year: 2018

A New Herbal Source of Synthesizing Contrast Agents for Magnetic Resonance Imaging

Authors: A. Yazdani, A. Okhovat, R. Doosti, H. Soltanian‐Zadeh

Journal: International Journal of Imaging Systems and Technology

Volume: 34 (4), e23136

Citations: Not available (2024 publication)

Year: 2024

Modification of a Herbal MRI Contrast Agent: Biological Effect and Relaxivity

Authors: A. Yazdani, A. Okhovat, R. Doosti, M. Saber, H. Soltanian-Zadeh

Conference: 2023 30th National and 8th International Iranian Conference on Biomedical 


Citations: Not available

Year: 2023

 

 

 

Prof. Junfa Zhu | Surface Chemistry Award | Best Scholar Award

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Prof. Junfa Zhu | Surface Chemistry Award | Best Scholar Award 

Prof. Junfa Zhu ,University of Science and Technology of China ,China

Dr. Junfa Zhu is a Chair Professor at the National Synchrotron Radiation Laboratory (NSRL), University of Science and Technology of China (USTC). He earned his Ph.D. in Physical Chemistry from USTC in 1999. His postdoctoral and research tenure included positions at Johannes-Kepler-UniversitĂ€t Linz (Austria), Friedrich-Alexander-UniversitĂ€t Erlangen-NĂŒrnberg (Germany), and the University of Washington (USA). Returning to USTC in 2006 under the “Hundred Talent Program” by the Chinese Academy of Sciences, Dr. Zhu has been pivotal in advancing surface science research. His work emphasizes in-situ surface chemistry, functional material interfaces, and synchrotron radiation techniques. With over 460 peer-reviewed publications, including Nature Communications and J. Am. Chem. Soc., his contributions have garnered 40,000+ citations and an impressive H-index of 102. As an editor for Surface Science Reports and other journals, Dr. Zhu also manages two soft X-ray spectroscopy endstations at NSRL, facilitating cutting-edge scientific investigations.

Professional Profile:

Orcid 

Scopus

Summary of Suitability for Award:

Dr. Junfa Zhu is an exemplary candidate for the “Best Scholar Award” due to his outstanding contributions to the field of surface science and material chemistry. With over 460 peer-reviewed publications in top-tier journals like Nature Communications, J. Am. Chem. Soc., and Angew. Chem. Int. Ed., his work has garnered more than 40,000 citations, achieving an impressive H-index of 102. Dr. Zhu’s research has significantly advanced the understanding of in-situ surface chemistry, functional material interfaces, and synchrotron radiation techniques. Dr. Junfa Zhu exemplifies the qualities of an outstanding scholar: exceptional research productivity, international recognition, and substantial contributions to scientific advancements.

🎓Education:

Dr. Junfa Zhu completed his Ph.D. in Physical Chemistry at the University of Science and Technology of China (USTC), where he focused on advanced surface science methodologies. His academic foundation provided him with the expertise to investigate the intricate behaviors of chemical interactions and surface properties. Postdoctoral research at prestigious institutions further expanded his knowledge base. At Johannes-Kepler-UniversitĂ€t Linz in Austria, he explored experimental physics, while his tenure at Friedrich-Alexander-UniversitĂ€t Erlangen-NĂŒrnberg in Germany deepened his specialization in physical chemistry. His research at the University of Washington in the United States provided him with hands-on experience in studying surface and interface structures in functional materials. This rigorous academic and research training equipped Dr. Junfa Zhu with interdisciplinary skills and a profound understanding of cutting-edge surface science techniques, laying the groundwork for his distinguished career in synchrotron radiation and material chemistry.

🏱Work Experience:

Dr. Junfa Zhu has cultivated an illustrious career that spans international institutions and interdisciplinary research. His postdoctoral appointments in Austria, Germany, and the United States honed his expertise in experimental physics, physical chemistry, and material science. He joined the University of Science and Technology of China as a professor, bringing global perspectives and advanced methodologies to his role. At the National Synchrotron Radiation Laboratory, he oversees two state-of-the-art soft X-ray spectroscopy endstations, enabling groundbreaking studies in surface chemistry and material interfaces. As an editor for influential journals, including Surface Science Reports, Dr. Junfa  Zhu contributes to advancing scientific dialogue in his field. His leadership and extensive collaborations have positioned him as a key figure in bridging fundamental research with real-world applications, further cementing his role as a leader in the scientific community and a catalyst for innovation in surface science.

🏅Awards:

Dr. Junfa Zhu has earned numerous accolades for his extraordinary contributions to surface science and material chemistry. His recognition under prestigious programs highlights his research excellence and potential to drive innovation in scientific discovery. He has received the National Science Fund for Distinguished Young Scholars, an acknowledgment of his groundbreaking studies in surface and interface chemistry. Designated as a Highly Cited Researcher, his extensive publications and remarkable citation impact underscore his global influence. As an editor for journals like Surface Science Reports, he has been acknowledged for his thought leadership in the academic community. Additionally, his role in managing state-of-the-art synchrotron facilities reflects his technical expertise and commitment to advancing experimental methodologies. These accolades, combined with his extensive contributions to high-impact journals, affirm Dr. Junfa  Zhu’s exceptional standing as a leader in the scientific community and a recipient of numerous prestigious honors.

🔬Research Focus:

Dr. Junfa Zhu’s research revolves around the innovative study of surface chemistry and functional materials using advanced experimental techniques. His work focuses on in-situ investigations of chemical reactions at surfaces, unraveling the complex interactions that govern material properties. He specializes in the structural and chemical analysis of interfaces in functional materials, which has implications for catalysis, nanotechnology, and material design. Leveraging advanced synchrotron radiation tools, Dr. Junfa Zhu explores atomic-level phenomena, providing critical insights into dynamic surface processes. His leadership in managing soft X-ray spectroscopy facilities enables cutting-edge experiments that bridge fundamental science and applied technology. His research has advanced the understanding of material behaviors under operational conditions, driving innovation in sustainable energy, electronic devices, and catalytic systems. Through interdisciplinary collaboration and a focus on real-time surface studies, Dr. Junfa  Zhu has made transformative contributions to the fields of material science and surface chemistry.

Publication Top Notes:

  • “Recent progress on surface chemistry II: Property and characterization”
      Citations: 3
  • “Recent progress on surface chemistry I: Assembly and reaction”
      Citations: 3
  • “Recent progress in on-surface synthesis of nanoporous graphene materials”
      Citations: 1
  • “Dualistic insulator states in 1T-TaS2 crystals”
      Citations: 1
  • “Substrate-modulation effect in on-surface synthesis”

 

 

 

Mon Hosseini-sarvari | Nanotechnology | Women Researcher Award

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Prof Dr. Mon Hosseini-sarvari | Nanotechnology | Women Researcher Award

Full prof. of organic chemistry of Shiraz University,  Iran

Seyedeh Mona Hosseini-Sarvari, born on November 17, 1972, in Shiraz, Iran, is a distinguished chemist specializing in organic chemistry and photochemistry. She earned her B.Sc., M.Sc., and Ph.D. from Shiraz University, where she now serves as a Full Professor. With an impressive academic trajectory, Dr. Hosseini-Sarvari has held visiting professorships at the University of Pennsylvania and has contributed significantly to chemical education and research. Her work is widely recognized, placing her among the top 2% of scientists globally. She has been awarded for her highly cited research papers and excellence in teaching. Her administrative roles at Shiraz University and involvement in various scientific committees reflect her dedication to advancing chemistry. Dr. Hosseini-Sarvari’s research focuses on developing innovative methodologies in organic synthesis and photochemistry, making significant contributions to the field.

Professional Profile:

Education:

Seyedeh Mona Hosseini-Sarvari completed her high school education at Asieh High School in Shiraz, Iran, graduating in June 1991. She then pursued a B.Sc. in Pure Chemistry at Shiraz University, Iran, from September 1992 to June 1996. Following her undergraduate studies, she continued at Shiraz University for her M.Sc. in Organic Chemistry from September 1996 to January 1999. She subsequently earned her Ph.D. in Organic Chemistry from the same institution, completing her doctoral studies in June 2003.

Professional Experience:

Dr. Hosseini-Sarvari has had a distinguished academic career at Shiraz University, Iran, beginning as an Assistant Professor from February 2004 to June 2008. She was then promoted to Associate Professor, a position she held from June 2008 to May 2014, before being appointed as a Full Professor in May 2014. She has also enriched her experience through several visiting professorships at the Roy and Diana Vagelos Laboratories, Department of Chemistry, University of Pennsylvania, USA, in 2012-2013, 2014, and 2017, under the supervision of Prof. Gary A. Molander. Additionally, she served as an Invited Professor at the University of Sulaimanie, Iraq, from 2020-2021, and at Huazhong University of Science and Technology (HUST), China, in 2023.

Research Interest:

Dr. Hosseini-Sarvari’s research interests lie primarily in the field of organic chemistry, with a focus on photochemistry and the synthesis of fine chemicals. Her work encompasses a broad spectrum of topics within organic synthesis, emphasizing the development of new methodologies and applications of photochemical processes in creating valuable chemical compounds.

Awards and Honors:

Throughout her career, Dr. Hosseini-Sarvari has received numerous awards and honors. She was recognized with the Most Cited Paper Award by Elsevier Ltd., Oxford, UK, for the period 2005-2008. She is also listed among the top 2% of scientists worldwide in all scientific fields. Her excellence in education has been acknowledged with the Distinguished Professor of Education award at Shiraz University for the academic years 2007-2008 and 2017-2018. Additionally, she has been honored as a Distinguished Research Professor for the years 2010-2011 and 2021-2022. Other notable accolades include the Award for the Development of Education Level and Writing Books in 2010-2011 and being the first rank student in her Ph.D. and M.Sc. programs in 2003 and 1999, respectively.

Research Skills:

Dr. Hosseini-Sarvari possesses a diverse set of research skills, particularly in organic synthesis and photochemistry. Her expertise includes the design and execution of complex chemical reactions, development of new synthetic methodologies, and application of photochemical techniques to create innovative chemical products. She is proficient in various laboratory techniques and instrumental analysis, contributing significantly to advancements in her field.

Publication:

  1. Title: A comparative study on the photocatalytic performance of modified graphitic carbon nitride (g-C3N4) with non-metals (P, B, S) for aerobic oxidative desulfurization
    • Authors: Z. Fouladi, S. Saki, M. Hosseini-Sarvari
    • Journal: Journal of Photochemistry and Photobiology A: Chemistry
    • Year: 2024
    • Citation: 453, 115652
  2. Title: Photoswitchable Catalytic Aerobic Oxidation of Biomass-Based Furfural: A Selective Route for the Synthesis of 5-Hydroxy-2 (5H)-furanone and Maleic Acid by Using the CdS/MOF
    • Authors: S. Saki, M. Hosseini-Sarvari, Y. Gu, T. Zhang
    • Journal: Industrial & Engineering Chemistry Research
    • Year: 2024
  3. Title: Innovative Porous Organic Polymer Incorporating Ferrocene and s-Triazine: An Effective Method for Converting Nitroarenes to Benzimidazoles Using Visible Light
    • Authors: M. Bashiri, T. Zhang, Y. Gu, M. Hosseini-Sarvari
    • Journal: Polymer
    • Year: 2024
    • Citation: 127141
  4. Title: A new dual nickel/ferrocenyl-chalcone as photoredox catalyst along with DFT studies for the three-component domino performance
    • Authors: M. Bashiri, M. Hosseini-Sarvari, S. Fakhraee
    • Journal: Journal of Photochemistry and Photobiology A: Chemistry
    • Year: 2024
    • Citation: 115494
  5. Title: Bis-ferrocenyl-hydrazide metal complexes: studying electronic functional groups as newly potent homogeneous photocatalysts for C (sp 3)–H and C (sp 2)–H bond oxidation
    • Authors: M. Bashiri, M. Hosseini-Sarvari, S. Fakhraee
    • Journal: Molecular Systems Design & Engineering
    • Year: 2024
    • Citation: 9 (1), 112-139
  6. Title: Methylene blue as an additive for acid-acid-catalyzed tandem reactions targeting on the synthesis of nitrogen-containing heterocycles
    • Authors: F. Huang, L. Guo, S. Chen, S. Saki, M. Hosseini-Sarvari, M. Li, R. Wang, R. Bai
    • Journal: Molecular Catalysis
    • Year: 2023
    • Citation: 547, 113293
  7. Title: Solvent-free visible-light-mediated α-phosphorylation and Csp3-H activation of tertiary and secondary amines at room temperature in the presence of cadmium
    • Authors: S. Firoozi, M. Hosseini-Sarvari
    • Journal: Photochemical & Photobiological Sciences
    • Year: 2023
    • Citation: 22 (8), 1839-1853
  8. Title: Visible-Light-Responsive Nano CuO/ZnO Photocatalyst for Chan–Lam Coupling Reaction and Aerobic C (sp3)–H Bond Oxidation
    • Authors: M.R. Daneshvar, M. Tavakolian, M. Hosseini-Sarvari
    • Journal: Synthesis
    • Year: 2023
    • Citation: 55 (16), 2495-2502
  9. Title: Nickel/TiO2-catalyzed Suzuki–Miyaura cross-coupling of arylboronic acids with aryl halides in MeOH/H2O
    • Authors: M. Hosseini-Sarvari, A. Dehghani
    • Journal: Monatshefte fĂŒr Chemie-Chemical Monthly
    • Year: 2023
    • Citation: 154 (3), 397-405
  10. Title: From expired metformin drug to nanoporous N-doped-g-C3N4: Durable sunlight-responsive photocatalyst for oxidation of furfural to maleic acid
    • Authors: M.R. Ebrahimian, M. Tavakolian, M. Hosseini-Sarvari
    • Journal: Journal of Environmental Chemical Engineering
    • Year: 2023
    • Citation: 11 (2), 109347