Juan de Pablo | Materials Science | Best Researcher Award

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Prof. Juan de Pablo | Materials Science | Best Researcher Award

Professor and Vice President from New York University, United States

Dr. Juan José de Pablo is a globally recognized leader in molecular engineering, materials science, and chemical engineering, known for his groundbreaking research and extensive leadership in academic and national scientific organizations. Currently serving as the Executive Vice President for Global Science and Technology and Executive Dean at the Tandon School of Engineering, New York University, Dr. de Pablo has had an illustrious academic and professional journey. He is also a senior scientist at Argonne National Laboratory and has held pivotal roles at the University of Chicago and the University of Wisconsin. His work spans multiple research areas, including directed self-assembly of polymers, soft materials, molecular simulation, and biotechnology. Over the years, Dr. de Pablo has established himself as a prolific researcher with over 20 patents, numerous influential publications, and editorial positions in high-impact journals. He is an elected member of prestigious institutions including the U.S. National Academy of Sciences, the National Academy of Engineering, and the American Academy of Arts and Sciences. His leadership has influenced science policy, strategic research initiatives, and interdisciplinary collaborations across the globe. His contributions are not only scientific but visionary, paving the way for future technological advances in materials design, nanotechnology, and energy solutions.

Professional Profile

Education

Dr. de Pablo’s academic foundation is as impressive as his professional accomplishments. He began his education at the National University of Mexico (UNAM), where he earned a Bachelor of Science in Chemical Engineering in 1985. His passion for chemical engineering led him to pursue a doctoral degree at the University of California, Berkeley, where he received his Ph.D. in Chemical Engineering in 1990. After completing his doctorate, he furthered his research capabilities during a postdoctoral fellowship in Materials Science at the Institute for Polymers, ETH Zurich, Switzerland, from 1990 to 1992. These formative years provided him with a robust interdisciplinary background that blends engineering principles with advanced materials science. His exposure to leading institutions in North America and Europe gave him a global perspective early in his career, which continues to shape his international collaborations and leadership roles. The rigorous training he received laid the groundwork for his expertise in thermodynamics, polymer physics, and computational modeling, which would go on to influence countless innovations in both academic and industrial domains.

Professional Experience

Dr. de Pablo’s professional career spans over three decades and includes a distinguished trajectory of teaching, research, and leadership. He began his academic career as an Assistant Professor of Chemical Engineering at the University of Wisconsin in 1992, rising through the ranks to become a full professor and eventually Director of its Materials Research Science and Engineering Center. From 2000 to 2012, he also served as Deputy Director of the Nanoscale Science and Engineering Center. In 2012, he joined the University of Chicago as the Liew Family Professor at the Institute for Molecular Engineering, and later took on pivotal roles including Co-Director of the Center for Hierarchical Materials Design (CHiMaD) and Deputy Director for Education and Outreach. Since 2018, he has also been CEO of UChicago-Argonne LLC. Dr. de Pablo’s influence extends beyond academia into national and global science leadership, particularly through his vice presidency roles related to U.S. National Laboratories and global innovation. In 2024, he was appointed Executive Dean at NYU’s Tandon School of Engineering, a role through which he continues to shape engineering education and research strategy. His extensive professional background reflects a unique combination of scientific innovation and strategic governance.

Research Interests

Dr. de Pablo’s research interests are both broad and deep, focusing on the intersection of molecular engineering, materials science, and computational physics. A primary focus of his work is on the directed self-assembly of block copolymers, a field in which he has pioneered several methodologies now used in nanomanufacturing and lithography. He also investigates thermophysical properties of soft materials, advanced polymer systems, biological interfaces, and molecular thermodynamics. His interest in computational modeling has led to the development of new simulation tools and theoretical frameworks for studying molecular and nanoscale systems, facilitating predictions of material behavior with high accuracy. Additionally, Dr. de Pablo has contributed significantly to biotechnology research, particularly in areas related to cryopreservation, stem cell engineering, and synthetic biology. His interdisciplinary approach allows him to tackle complex problems that span chemistry, physics, and engineering. Through collaborative projects and centers such as CHiMaD, he works closely with experimentalists to translate computational models into real-world applications. His research agenda reflects an enduring commitment to solving fundamental scientific challenges while also addressing practical issues in health, energy, and technology.

Research Skills

Dr. de Pablo possesses an exceptional array of research skills that reflect his training and contributions across multiple scientific disciplines. He is a world leader in computational modeling and molecular simulation, applying these techniques to study the thermodynamic and kinetic behavior of polymers, colloids, and biological systems. His skillset includes advanced knowledge of coarse-grained and multiscale simulations, free energy calculations, and structure-property prediction methods. Beyond computational proficiency, he has deep expertise in thermodynamics, statistical mechanics, and polymer physics. His laboratory and theoretical work complement each other, allowing him to bridge gaps between experimental observations and theoretical predictions. He is also adept at integrating interdisciplinary methods, including those from materials science, chemical engineering, and applied physics. His ability to conceptualize and lead large-scale research initiatives, such as the Materials Genome Initiative, highlights his strengths in research strategy and innovation management. In mentoring and supervision, Dr. de Pablo has guided dozens of Ph.D. students and postdoctoral fellows, instilling in them a rigorous and holistic research methodology. His technical versatility and collaborative mindset are key reasons behind his influential role in shaping modern materials science.

Awards and Honors

Dr. de Pablo has been the recipient of numerous prestigious awards and honors that reflect the depth, breadth, and impact of his scientific career. Early in his career, he received multiple young investigator awards from leading institutions like NSF, IBM, Xerox, 3M, and DuPont, signaling his early promise. He went on to receive the Presidential Faculty Fellow Award from President Bill Clinton and was later elected as a Fellow of the American Physical Society and the American Academy of Arts and Sciences. His research has been recognized through lectureships and invited professorships at top global institutions such as ETH Zurich, Stanford, and the University of Michigan. He has delivered keynote talks and plenary lectures at more than 30 prestigious conferences and universities worldwide. In 2016, he was elected to the U.S. National Academy of Engineering and later to the National Academy of Sciences in 2022. Internationally, he holds honors like the Marie Curie Professorship and the Chevalier de l’Ordre du Mérite (France, 2024). His accolades also include the Polymer Physics Prize from the American Physical Society and numerous distinguished lectureships from Caltech, MIT, Princeton, and others. These honors underline his status as a leading global authority in materials and molecular engineering.

Conclusion

Dr. Juan José de Pablo exemplifies excellence in scientific research, innovation, and leadership. His prolific academic career, paired with his impactful administrative and advisory roles, highlights a rare combination of deep technical expertise and visionary leadership. His contributions to molecular engineering and materials science have not only expanded fundamental scientific understanding but have also enabled new technologies in fields ranging from nanolithography to cryopreservation. With over 20 patents, numerous high-impact publications, and a strong track record of mentorship, Dr. de Pablo has influenced both the academic community and industrial applications. His election to multiple national academies and his global recognition through prestigious awards are testaments to the quality and impact of his work. While already an established authority, he continues to contribute actively through roles in science policy, research strategy, and education at the highest levels. In summary, Dr. de Pablo’s lifelong dedication to advancing science and mentoring the next generation of researchers makes him a truly deserving candidate for the Best Researcher Award. His career serves as an inspiration and a benchmark for excellence in global scientific leadership.

Publications Top Notes

  1. Water-mediated ion transport in an anion exchange membrane
    Nature Communications, 2025
    Citations: 2
  2. Structural studies of the IFNλ4 receptor complex using cryoEM enabled by protein engineering
    Nature Communications, 2025
    Citations: 1
  3. Reflection and refraction of directrons at the interface
    Proceedings of the National Academy of Sciences of the United States of America, 2025
  4. Free-Energy Landscapes and Surface Dynamics in Methane Activation on Ni(511) via Machine Learning and Enhanced Sampling
    ACS Catalysis, 2025
  5. Synthetic Active Liquid Crystals Powered by Acoustic Waves
    Advanced Materials, 2025
  6. Current Advances in Genome Modeling Across Length Scales 2025
  7. Chromatin structures from integrated AI and polymer physics model
    PLOS Computational Biology, 2025
    Citations: 1
  8. A Twist on Controlling the Equilibrium of Dynamic Thia-Michael Reactions
    Journal of Organic Chemistry, 2025
  9. Bio-Based Surfactants via Borrowing Hydrogen Catalysis
    Chemistry – A European Journal, 2025
  10. Efficient sampling of free energy landscapes with functions in Sobolev spaces
    Journal of Chemical Physics, 2025
    Citations: 1

Hadi Hijazi | Materials Science | Best Researcher Award

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Dr. Hadi Hijazi | Materials Science | Best Researcher Award

R&D engineer from CEA LETI, France

Dr. Hadi Hijazi is a postdoctoral researcher specializing in microelectronics and semiconductor nanostructures, with extensive experience in epitaxial growth and device fabrication. Based in Grenoble, France, he has developed a strong academic and research background through work at top-tier institutions such as CEA-LETI, CNRS/LTM, and Saint Petersburg State University. His research encompasses the design, modeling, and experimental development of III-V materials and nanostructures for high-performance optoelectronic devices, including visible and near-infrared LEDs. His doctoral studies focused on the epitaxial growth of GaAs nanowires via HVPE and the investigation of spin and charge transport. Dr. Hijazi possesses deep technical expertise in MOCVD, HVPE, and cleanroom operations, supported by his proficiency in a wide range of characterization tools such as XRD, SEM, AFM, PL, and Raman spectroscopy. In addition to his laboratory capabilities, he is skilled in modeling and simulation using tools like Matlab, Nextnano, and Mathematica. Multilingual and collaborative, Dr. Hijazi has a history of successful international projects, combining both theoretical insight and experimental innovation. His contributions to the field are reflected in quality publications in peer-reviewed journals, and he maintains active connections with research leaders and institutions in France and abroad. He is currently an R&D engineer at CEA LETI, contributing to hybrid bonding technologies.

Professional Profile

Education

Dr. Hadi Hijazi holds a Ph.D. in Physics of Materials from Institut Pascal at Université Clermont Auvergne, France, where he worked on the development of GaAs nanowires grown on Si substrates using hydride vapor phase epitaxy (HVPE). His research addressed charge and spin diffusion in nanowires, integrating fundamental physics with advanced material synthesis techniques. Prior to his doctoral studies, Dr. Hijazi completed a Master’s degree (M2) in Nanoelectronics and Nanotechnology from Université Grenoble Alpes, where he received training in nanoscale materials, semiconductor physics, and cleanroom-based device fabrication. He also holds a Master 1 in Fundamental Physics and Nanoscience from Université Joseph Fourier in Grenoble, which laid the foundation for his later specialization in materials and device engineering. His academic training has been interdisciplinary, with strong emphasis on physics, nanotechnology, materials science, and applied electronics. His formal education has equipped him with theoretical depth and practical skill sets, enabling his contributions to multidisciplinary research involving physical modeling, simulation, and experimental validation of micro- and nanoscale structures. These qualifications have prepared him well for complex problem-solving in research-intensive environments, particularly within the highly competitive field of semiconductor materials and microelectronics.

Professional Experience

Dr. Hadi Hijazi has accumulated a robust portfolio of research and development experience across premier academic and industrial research institutions. Since July 2023, he has been serving as an R&D Engineer at CEA LETI in Grenoble, where he works on hybrid bonding technologies, a critical area for 3D integration in microelectronics. From October 2021 to June 2023, he served as a postdoctoral researcher jointly at CEA-LETI and CNRS/LTM, contributing to the IRT Nanoelec project. During this tenure, he focused on the design and simulation of novel heterostructures using III-(As,P) materials for high-performance visible and NIR LEDs. His work included epitaxial process development (MOCVD) on 300 mm substrates and comprehensive characterization of material and device properties. Prior to this, he was a postdoctoral researcher at ITMO University and Saint Petersburg State University in Russia, focusing on growth modeling of III-V and IV-IV micro/nanostructures. Dr. Hijazi also undertook an industrial internship at CEA LETI in 2016, studying the bonding of refractory metal thin films for 3D technologies. Throughout his career, he has demonstrated the ability to integrate theory, simulation, and fabrication in practical research, aligning well with multidisciplinary goals in microelectronics and optoelectronics innovation.

Research Interests

Dr. Hadi Hijazi’s research interests center around advanced semiconductor materials and their integration into high-performance optoelectronic and microelectronic devices. He is particularly focused on the design, epitaxial growth, and characterization of III-V compound semiconductors on silicon substrates, with the goal of enabling new generations of energy-efficient light sources and integrated photonics. His doctoral work involved HVPE growth of GaAs nanowires on Si(111) substrates, aiming to understand charge and spin transport mechanisms at the nanoscale. His postdoctoral research extended to MOCVD-based fabrication of InGaAs and InP heterostructures for LED applications and included structural and electro-optical characterization. He is also interested in hybrid bonding technologies and 3D integration techniques critical to the future of chip stacking and packaging. Dr. Hijazi combines experimental efforts with simulation and modeling, employing tools like Matlab and Nextnano to optimize nanostructure design and predict growth behavior. He is deeply engaged in the physical understanding of epitaxy, surface/interface interactions, and defect formation. These interests place him at the intersection of materials physics, nanotechnology, and applied engineering, with relevance to optoelectronics, spintronics, and next-generation semiconductor device platforms.

Research Skills

Dr. Hadi Hijazi possesses a comprehensive set of research skills that span theoretical modeling, experimental techniques, and process development in nanotechnology and materials science. His expertise in vapor phase epitaxy, including both MOCVD and HVPE methods, allows him to develop high-quality III-V semiconductor nanostructures on various substrates. He has extensive cleanroom experience and is adept in device fabrication processes, material growth protocols, and post-growth characterization. He is proficient in a range of analytical tools such as XRD, AFM, SEM, Raman spectroscopy, photoluminescence (PL), and electrochemical and C-V measurements. Dr. Hijazi is also skilled in simulation and modeling, using software like Matlab, Mathematica, Nextnano, Python, and C++ to analyze material behaviors and guide experimental design. His strong command of semiconductor physics and nanostructure dynamics supports both fundamental research and practical application development. He is an effective communicator in French, English, and Arabic, and his collaborative approach to research is evident in his successful engagements with multidisciplinary teams across France and Russia. Additionally, his organizational and documentation skills are well-developed, contributing to his ability to manage complex research tasks and publish high-quality scientific articles.

Awards and Honors

While specific named awards are not listed in the available information, Dr. Hadi Hijazi’s inclusion in competitive research programs and positions at prestigious institutions such as CEA-LETI, CNRS, and ITMO University itself serves as recognition of his capabilities and achievements. His acceptance into highly selective doctoral and postdoctoral programs in France and Russia, coupled with his contributions to projects such as IRT Nanoelec, suggests a high degree of merit and recognition by the scientific community. His publications in internationally recognized journals such as Nanotechnology and Journal of Physical Chemistry C also indicate the quality and impact of his research. Furthermore, his involvement in international collaborations and multidisciplinary research teams demonstrates the professional trust placed in his expertise and reliability. His continuing employment at CEA LETI in a research and development role is itself a form of institutional endorsement, affirming his value in the innovation ecosystem of advanced microelectronics. With further dissemination of his work and engagement in academic presentations or grant-funded leadership, it is likely he will accrue formal honors and awards in the near future.

Conclusion

Dr. Hadi Hijazi is an accomplished early-career researcher with strong potential for further growth in the field of semiconductor nanotechnology and microelectronics. His academic training and international research experience have equipped him with both depth and versatility, enabling contributions to next-generation devices through innovations in epitaxial growth, material design, and device integration. His ability to bridge theoretical modeling with experimental realization is a key asset, particularly in collaborative research environments. While his current achievements position him as a valuable team member and emerging expert, more visible research leadership, independent project development, and broader dissemination of research outputs could further strengthen his candidacy for major research awards. At present, Dr. Hijazi would be an ideal candidate for recognitions aimed at emerging scientists or rising researchers, and with continued productivity and impact, he is well-poised to become a leading figure in semiconductor device research. His technical expertise, commitment to quality, and collaborative ethos make him a noteworthy contributor to academic and industrial R&D. As he continues his career at CEA LETI and beyond, further contributions in both applied technologies and fundamental science can be expected.

Publications Top Notes

  1. Fine Pitch Superconducting Interconnects Obtained with Nb–Nb Direct Bonding

  • Authors: Candice M. Thomas, Pablo Renaud, Meriem Guergour, Edouard Deschaseaux, Christophe Dubarry, Jennifer Guillaume, Elisa Vermande, Alain Campo, Frank Fournel, Hadi Hijazi, Anne-Marie Papon, Catherine Pellissier, Jean Charbonnier

  • Publication Year: 2025

2. Is NaOH Beneficial to Low Temperature Hybrid Bonding Integration?

  • Authors: Hadi Hijazi¹, Paul Noël¹, Samuel Tardif², Karine Abadie¹, Christophe Morales¹, Frank Fournel¹

  • Publication Date: October 30, 2024

 

Feng Wang | Materials Science | Best Researcher Award

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Prof. Feng Wang | Materials Science | Best Researcher Award

Professor at Southwest University, China

Feng Wang is a Professor at the Biological Research Center of Southwest University, China, specializing in molecular biology, genetic engineering, and biomaterials. He earned his Ph.D. in Biochemistry and Molecular Biology from Southwest University in 2014. Wang’s research focuses on genetic modification of silkworms to produce functional biomaterials and recombinant proteins for biomedical applications, such as tissue engineering and drug delivery. His work on genome editing using CRISPR/Cas9 and other techniques has led to significant advancements in bio-functional silk production. Wang has published extensively in high-impact journals, contributing to the fields of biotechnology and bioengineering. He has also held roles as a visiting scholar and postdoctoral researcher at various institutions. His groundbreaking research continues to make valuable contributions to the development of innovative medical technologies.

Professional Profile

Education and Work Experience:

Feng Wang completed his undergraduate degree in Bioengineering at the College of Life Science, Southwest University, Chongqing, China, graduating in 2008. He pursued advanced studies at the same institution, earning a Ph.D. in Biochemistry and Molecular Biology from the State Key Laboratory of Silkworm Genome Biology, Southwest University, in 2014. During his academic career, he has held several important positions. He became an Associate Professor at Southwest University in 2018, and in 2023, he was promoted to a full Professor at the Biological Research Center of the university. Wang has also gained valuable international experience as a visiting scholar at Tufts University, USA, from 2018 to 2019. Before this, he served as a research associate and postdoctoral researcher at Southwest University’s College of Biotechnology, contributing significantly to the fields of molecular biology and biotechnology. His career trajectory showcases his growing expertise and leadership in the scientific community, particularly in genetic engineering and biomaterial development, where he continues to make notable contributions to both academia and industry.

Research Interests and Contributions:

Feng Wang’s primary research interests focus on the genetic modification of silkworms and other insect species to enhance functional biomaterials. He specializes in genome editing techniques such as CRISPR/Cas9, TALEN, and ZFN to regulate gene expression and modify silkworm genomes for various applications. Wang has pioneered the use of genetically engineered silkworm spun silk as a potential biomaterial for biomedical purposes, including tissue engineering. His work on producing recombinant pharmaceutical proteins, such as growth factors, human lactoferrin, and human serum albumin, within silkworms, has significant implications for cost-effective, large-scale production of valuable biomolecules. Wang’s research also explores the use of silkworm silk glands as bioreactors for producing proteins with therapeutic applications. His recent studies emphasize the development of silk-based materials for tissue regeneration and other medical uses, demonstrating his ability to bridge molecular biology, biotechnology, and material science. His interdisciplinary work continues to advance the potential of silkworms in producing bio-functional materials with wide-ranging biomedical applications.

Publications and Achievements:

Feng Wang has authored and co-authored numerous high-impact publications in renowned scientific journals. His work spans diverse topics, with a particular focus on genetic engineering, biomaterials, and recombinant protein production. Notable recent publications include articles in Advanced Materials, Biomaterials, and Insect Science, with research exploring the production of functional silk fibroin-based biomaterials and the application of transgenic silkworms for large-scale recombinant protein production. Wang has contributed significantly to advancements in silk engineering, including the fabrication of silk sericin hydrogels for tissue repair and the development of silk-based systems for the delivery of therapeutic proteins. His collaborative approach has also led to joint publications with international researchers, further expanding the impact of his research. Wang’s scientific contributions have received global recognition, and his work continues to inspire advancements in bioengineering and biotechnology. He is also an active member of various research networks and collaborations, facilitating the exchange of knowledge and ideas across the global scientific community. With a growing body of work, his research continues to address pressing challenges in biomedical applications, making him a recognized leader in his field.

Strengths for the Award:

Feng Wang’s research is highly innovative and interdisciplinary, merging molecular biology, genetic engineering, and biomaterial science to address key challenges in biomedical applications. His expertise in genome editing, especially in transgenic silkworms, positions him as a leading figure in the development of functional biomaterials for medical use. Wang’s ability to apply cutting-edge techniques such as CRISPR/Cas9, TALEN, and ZFN for silkworm genetic modification has resulted in the creation of valuable materials, including recombinant pharmaceutical proteins and tissue-engineering scaffolds. His work in engineering silkworm spun silk to express functional proteins demonstrates both creativity and technical proficiency, allowing for the large-scale production of bio-functional biomaterials with significant medical potential. Wang’s leadership as an academic researcher and his extensive publication record, including high-impact journals with broad citations, further demonstrate his research excellence. His collaborative approach with both domestic and international research communities enhances the relevance and impact of his contributions. Overall, his continuous pursuit of innovative solutions for biomedical applications underscores his potential as a strong contender for the Best Researcher Award.

Areas for Improvement:

While Feng Wang has made significant contributions to his field, there are areas where his work can be further expanded to maximize its impact. One potential area for improvement is broadening the scope of his research to include more diverse applications of genetically modified silkworms, particularly in the context of personalized medicine or other innovative therapeutic strategies. Although Wang has focused heavily on protein production and tissue regeneration, there is room for exploring the potential of silkworm-based materials in other areas of biomedical engineering, such as drug delivery systems or diagnostic devices. Additionally, Wang could collaborate with industry partners to translate his findings into real-world applications more effectively. Strengthening his involvement in translational research could accelerate the commercialization of his discoveries, ensuring that his contributions have tangible benefits for society. Another area for improvement lies in the scalability and cost-efficiency of producing genetically modified silkworms and recombinant proteins, which could enhance the practicality and accessibility of his research outcomes. By addressing these challenges, Wang could further elevate the impact of his work and expand its application to broader sectors of healthcare.

Conclusion:

Feng Wang’s exceptional work in gene expression regulation, genome modification, and biomaterials development has significantly advanced the field of biotechnology, particularly in the context of biomedical applications. His pioneering research in genetically engineered silkworms has led to the creation of bio-functional silks that can be used in tissue engineering and the production of therapeutic proteins. With a proven track record of high-impact publications, international collaborations, and continuous innovation, Wang is a leading figure in his field. While there are areas where his research can expand, particularly in translating his findings into commercial applications and exploring additional biomedical uses for silkworm-derived materials, his contributions to science and technology are already substantial. Wang’s dedication to solving complex problems in biomedical engineering, combined with his technical expertise and visionary research, makes him a deserving candidate for the Best Researcher Award. His continued success and impact on the scientific community are promising, and his future work holds even greater potential for advancing healthcare technologies.

Publication Top Notes

  1. Title: Fabrication of a transforming growth factor β1 functionalized silk sericin hydrogel through genetical engineering to repair alveolar bone defects in rabbit
    • Authors: Wang, F., Ning, A., Sun, X., Ma, X., Xia, Q.
    • Year: 2025
  2. Title: Highly efficient expression of human extracellular superoxide dismutase (rhEcSOD) with ultraviolet-B-induced damage-resistance activity in transgenic silkworm cocoons
    • Authors: Wang, F., Wang, R., Zhong, D., Zhao, P., Xia, Q.
    • Year: 2024
    • Citations: 5
  3. Title: CRISPR/Cas9-Mediated Editing of BmEcKL1 Gene Sequence Affected Silk Gland Development of Silkworms (Bombyx mori)
    • Authors: Li, S., Lao, J., Sun, Y., Zhao, P., Xia, Q.
    • Year: 2024
    • Citations: 5
  4. Title: Antimicrobial mechanism of Limosilactobacillus fermentum SHY10 metabolites against pickle film-producing strain by metabolomic and transcriptomic analysis
    • Authors: Lian, Y., Luo, S., Song, J., Liu, K., Zhang, Y.
    • Year: 2024
  5. Title: An Efficient Biosynthetic System for Developing Functional Silk Fibroin-Based Biomaterials
    • Authors: Wang, F., Lei, H., Tian, C., Kaplan, D.L., Xia, Q.
    • Year: 2024
  6. Title: The different effects of molybdate on Hg(II) bio-methylation in aerobic and anaerobic bacteria
    • Authors: Wang, L., Liu, H., Wang, F., Wang, D., Shen, H.
    • Year: 2024
    • Citations: 1
  7. Title: Morusin shows potent antitumor activity for melanoma through apoptosis induction and proliferation inhibition
    • Authors: Liu, W., Ji, Y., Wang, F., Liu, Y., Cui, H.
    • Year: 2023
    • Citations: 3
  8. Title: Correction: Optimization of a 2A self-cleaving peptide-based multigene expression system for efficient expression of upstream and downstream genes in silkworm
    • Authors: Wang, Y., Wang, F., Xu, S., Zhao, P., Xia, Q.
    • Year: 2023