Viola Vogler-Neuling | 3D second harmonic photonic crystals | Best Researcher Award

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Dr. Viola Vogler-Neuling | 3D second harmonic photonic crystals | Best Researcher Award

Adolphe Merkle Institute | Switzerland

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Dr. Viola Valentina Vogler-Neuling began her academic journey with a Bachelor of Physics from ETH Zurich, where she graduated with distinction. She continued her studies at the same institution, earning a Master of Physics with a thesis on the strain-dependent electro-optical effect in BaTiO3 thin films on silicon. During her master’s program, she gained international experience through an exchange semester at Chalmers University of Technology in Sweden, focusing on quantum field theory, renewable energies, and liquid crystals. Her doctoral studies, also at ETH Zurich, culminated in a Ph.D. with a thesis on nonlinear photonic crystals and metasurfaces in soft-nanoimprinted barium titanate nanomaterials.

PROFESSIONAL ENDEAVORS

Dr. Vogler-Neuling’s professional career is marked by significant positions and responsibilities. As a postdoctoral researcher in the Optical Nanomaterial Group at ETH Zurich, she worked on 3D nonlinear woodpile photonic crystals in barium titanate sol-gel and co-supervised Ph.D. and Master’s students. Following this, she joined the Soft Matter Physics Group at the Adolphe Merkle Institute, Université de Fribourg, where she led the Biophotonics subgroup, studying the interplay between structural order and disorder in natural photonic crystals and developing artificial 3D photonic crystals from chitin and chitosan. Currently, she serves as a Group Leader at the same institute, focusing on bio-inspired photonics.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Vogler-Neuling’s research contributions are centered around the development and characterization of 3D second harmonic photonic crystals. Her work involves creating photonic crystal cavities and electro-optic metasurfaces using innovative bottom-up nanofabrication methods. She has made significant strides in the field of nonlinear optics, particularly with barium titanate nanoparticles. Her expertise extends to cleanroom nanofabrication and a variety of characterization techniques. She has also been instrumental in advancing bio-inspired photonics, exploring the optical properties of structures derived from natural materials.

IMPACT AND INFLUENCE

Dr. Vogler-Neuling’s research on 3D second harmonic photonic crystals has had a profound impact on the field of optical nanomaterials. Her work on developing large-scale nonlinear woodpile photonic crystals and electro-optic metasurfaces has been widely recognized, earning her several awards, including the Best Poster Award at the Complex Nanophotonics Science Camp. She has contributed significantly to the understanding of how structural order and disorder affect optical responses, influencing both theoretical and practical applications in photonics.

ACADEMIC CITES

Throughout her academic career, Dr. Vogler-Neuling has been actively engaged in teaching and mentoring. She has supervised numerous undergraduate and graduate students, guiding them in various projects related to photonic structures and materials science. Her contributions to education have been acknowledged through awards such as the Teaching Award from the Engaging Physics Tutoring Initiative at ETH Zurich. Her published works and conference presentations on 3D second harmonic photonic crystals have been cited by peers, demonstrating the academic impact of her research.

LEGACY AND FUTURE CONTRIBUTIONS

Dr. Vogler-Neuling's legacy in the field of photonics is characterized by her innovative approach to bio-inspired and nonlinear optical materials. Her future contributions are poised to further explore the applications of 3D second harmonic photonic crystals in various domains, including biophotonics and sustainable technologies. Her ongoing research and leadership in the Bio-inspired Photonics subgroup at the Adolphe Merkle Institute are expected to yield significant advancements in the understanding and utilization of photonic crystals derived from biological building blocks.

3D SECOND HARMONIC PHOTONIC CRYSTALS

Dr. Vogler-Neuling’s work with 3D second harmonic photonic crystals involves intricate nanofabrication techniques and advanced optical characterization methods. Her research in this area is pivotal for developing new photonic devices with enhanced nonlinear optical properties. The innovative approaches she has developed for fabricating and studying these crystals are setting new standards in the field, paving the way for future breakthroughs in photonic and optoelectronic technologies.

NOTABLE PUBLICATION

 

Umer Younis | Optical Properties | Best Researcher Award 

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Dr. Umer Younis | Optical Properties | Best Researcher Award 

University of Electronic Science and Technology of China | China

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Dr. Umer Younis, born on June 5, 1993, in Pakistan, has demonstrated an exceptional academic trajectory in the field of materials science and physics. He earned his B.S. (Honors) in Physics from Government College University, Faisalabad, followed by an M.S. in Physics from the University of Agriculture, Faisalabad. His academic excellence continued with a Ph.D. in Materials Physics and Chemistry from Peking University, one of the top-ranked universities globally (QS ranked 17), under a fully funded Chinese government scholarship. His Ph.D. research focused on computational materials design for energy applications, particularly emphasizing optical properties of materials, which has laid a strong foundation for his subsequent research career.

PROFESSIONAL ENDEAVORS

Dr. Younis is currently a Post-Doctoral Researcher at the Institute of Fundamental and Frontier Sciences (IFFS) at the University of Electronic Science and Technology of China (UESTC), a position he has held since November 2022. His work primarily involves advanced computational studies on materials, with a significant focus on optical properties and their implications for energy applications. His professional experience includes a visit to the École de Technologie Supérieure (ETS) in Montreal, Canada, in 2023, reflecting his active engagement in international research collaborations. Additionally, Dr. Younis has served as a lecturer in Physics at Kips College, Faisalabad, Pakistan, and currently reviews for several high-impact scientific journals.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Younis has made significant contributions to materials science, particularly through his research on optical properties and their role in energy materials. His expertise includes computational physics, theoretical physics, and the study of metal-ion batteries, electronic properties, and mechanical properties. He employs advanced methodologies such as first-principles calculations, density functional theory, and molecular dynamic simulations to explore and optimize the optical properties of various materials. His research has been recognized and supported by numerous awards and grants, including the prestigious Research Funds as an International Young Scientist from the National Natural Science Foundation of China for 2023-2024.

IMPACT AND INFLUENCE

Dr. Younis's research has had a profound impact on the field of materials science, particularly in understanding and enhancing the optical properties of materials for energy applications. His work has been awarded and recognized for academic excellence multiple times during his tenure at Peking University. He has been an invited speaker at several international conferences and symposia, highlighting his influence and recognition in the scientific community. His contributions as a reviewer for notable journals further underscore his role in advancing the quality and scope of research in his field.

ACADEMIC CITES

Dr. Younis's academic work is highly cited, reflecting the significance and impact of his research in materials science. His studies on the optical properties of materials and their applications in energy solutions are frequently referenced in scholarly articles and journals, demonstrating the relevance and application of his findings in advancing the field. His contributions have not only added to the academic knowledge base but have also inspired further research and development in related areas.

LEGACY AND FUTURE CONTRIBUTIONS

Dr. Younis's legacy in the field of materials science is marked by his innovative research and dedication to understanding and optimizing the optical properties of materials. His future contributions are anticipated to further advance the field, particularly in developing new materials with enhanced properties for energy applications. As he continues his post-doctoral research and engages in international collaborations, Dr. Younis is expected to remain at the forefront of materials science research, driving innovations and contributing significantly to the scientific community.

OPTICAL PROPERTIES

Throughout his career, Dr. Umer Younis has focused extensively on the optical properties of materials. His research aims to understand how these properties can be manipulated and optimized to improve material performance in energy applications. This focus on optical properties is central to his work and has led to significant advancements in materials science, particularly in the development of new and innovative energy solutions. As he continues his research, the study of optical properties will remain a key area, driving further discoveries and applications in the field.

NOTABLE PUBLICATION