Alma Cioci | Second Harmonic Generation Properties | Best Researcher Award

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Dr. Alma Cioci | Second Harmonic Generation Properties | Best Researcher Award 

Università degli studi di Torino | Italy

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Dr. Alma Cioci began her academic journey at the Università degli Studi di Torino, where she pursued her undergraduate and graduate studies in Chemistry. Her early academic work focused on the application of computational methodologies to crystalline systems, utilizing the quantum mechanical calculation program CRYSTAL. This foundational work laid the groundwork for her future research endeavors in the field of material sciences and optoelectronics.

PROFESSIONAL ENDEAVORS

Throughout her career, Dr. Cioci has been deeply involved in both theoretical and experimental research. She has held multiple research positions at the Università degli Studi di Torino, including roles as a research fellow and laboratory assistant. Her work primarily focuses on the synthesis and characterization of metalloorganic biosensors and new crystalline materials for diagnostics and radiotherapy in oncology. Since January 2022, Dr. Cioci has been a doctoral candidate working on the synthesis of metalloporphyrinates for the development of smart materials for optoelectronics, with a particular interest in Second Harmonic Generation Properties.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Cioci’s research has significantly contributed to the development of advanced materials with unique optical properties. Her doctoral research involves the crystallization and characterization of synthesized materials using single-crystal X-ray diffraction. Additionally, she employs computational modeling to study the hyperpolarizability and second-order optical susceptibility of these crystalline solids. This work is pivotal for the development of materials with enhanced Second Harmonic Generation Properties, which are crucial for optoelectronic applications.

IMPACT AND INFLUENCE

Dr. Cioci's work has had a notable impact on the field of materials science, particularly in the area of optoelectronics. Her research on Second Harmonic Generation Properties has opened new avenues for the development of materials that can be used in advanced optical devices. Her contributions have been recognized within the academic community, and her findings have influenced subsequent research in the field of nonlinear optics and material characterization.

ACADEMIC CITATIONS

Dr. Cioci's publications and research findings have been cited by her peers, highlighting the relevance and importance of her work in the field of chemistry and materials science. Her contributions to the understanding and development of materials with significant Second Harmonic Generation Properties have been acknowledged through various academic citations, underscoring her influence and the impact of her research.

LEGACY AND FUTURE CONTRIBUTIONS

Looking ahead, Dr. Alma Cioci aims to continue her research on the synthesis and characterization of advanced materials with unique optical properties. Her future work will likely explore further applications of Second Harmonic Generation Properties in optoelectronics and other related fields. Through her innovative research and dedication, Dr. Cioci is poised to leave a lasting legacy in the development of smart materials, contributing to advancements in technology and science.

SECOND HARMONIC GENERATION PROPERTIES 

Dr. Cioci’s extensive research on Second Harmonic Generation Properties has positioned her as a leading expert in this field. Her work encompasses the synthesis, crystallization, and computational modeling of materials with enhanced optical properties. The keywords associated with her research—Second Harmonic Generation Properties, optoelectronics, and material characterization—reflect the core areas of her contributions and highlight her expertise in developing innovative solutions for advanced materials and their applications.

NOTABLE PUBLICATION

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