PhD candidate at Zhejiang University of Technology, China
He Jiangle is a passionate Ph.D. candidate 🧑🎓 at Zhejiang University of Technology, China 🇨🇳, specializing in topological photonic crystals 🌌. His research focuses on the control and manipulation of multi-dimensional optical fields through the unique properties of light—such as spin, orbital angular momentum, frequency, polarization, and symmetry 🎯. Through innovative designs and simulations, he has made significant contributions to cutting-edge topics like higher-order topological states and their coupling with low-dimensional semiconductor excitons 💡. His impactful work has been published in several prestigious journals 📚 including Nano Letters and Photonics Research. A collaborative researcher, he has worked alongside leading institutions like Nanjing University and Huaqiao University 🧪. With a strong foundation in theory, computation, and academic writing ✍️, He Jiangle is steadily shaping the future of photonic topological physics, making him a deserving nominee for the Best Researcher Award 🏆.
Professional Profile:
Orcid
🔹 Education and Experience
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🎓 Ph.D. Candidate in Physics, Zhejiang University of Technology
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🔬 Research Area: Topological photonic crystals and multi-dimensional optical field control
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🏫 Collaborations: Nanjing University and Huaqiao University
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🧠 Expertise: Design, simulation, and theoretical modeling of photonic systems
🔹 Professional Development
He Jiangle is at the forefront of photonic research 🛰️, focusing on controlling and engineering topological states of light through innovative approaches. With a deep understanding of the optical properties of materials 🌈, he harnesses features such as spin, orbital angular momentum, and photonic symmetry to unlock novel functionalities in photonic crystals. His professional growth is evident from his consistently high-impact publications in Nano Letters 🧾 (JCR-Q1), Photonics Research 📘 (JCR-Q1), and Optics Express 🔍 (JCR-Q2). Actively engaged in all phases of research—from conceptual design and simulation to writing and peer-review communication ✍️—he demonstrates a robust command over both scientific and collaborative skills. With growing recognition in the photonics community, his academic rigor and innovative spirit 📐 continue to push boundaries in modern optics, ensuring his journey remains both impactful and inspirational 🚀.
🔹 Research Focus
He Jiangle’s primary research area is the study and application of topological photonic crystals 🧿. These are optical materials engineered to support special light modes that are resistant to defects and backscattering 💫. His work focuses on multi-dimensional topological photonic states, where he explores how light’s different properties—such as polarization 🌀, spin 🔄, and frequency ⚡—can be used to control light’s behavior in confined and complex systems. Particularly, he examines higher-order topological states and valley photonic crystals for their ability to create and confine light in corners or edges of photonic structures 🔲. His contributions bridge theory and application, exploring how such controlled light states can couple with low-dimensional semiconductor excitons to advance photonic computing and communication systems 🌐. His goal is to leverage these robust optical states to develop future-proof technologies in nanophotonics and quantum optics 🔬✨.
🔹 Awards and Honors
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🏆 Best Researcher Award Nominee – Recognized for significant contributions to topological photonics
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📄 Multiple Publications in High-Impact Journals – Such as Nano Letters (JCR-Q1), Photonics Research (JCR-Q1), and Optics Express (JCR-Q2)
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🌐 International Collaboration Recognition – With top Chinese institutions like Nanjing University
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📘 Cited Work – Highly cited research on photonic topological states and their dynamic control
Publication Top Notes
1. Directional Excitation of Multi-Dimensional Coupled Topological Photonic States Based on Higher-Order Chiral Source
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Journal: Photonics
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Publication Date: 2025-05-15
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DOI: 10.3390/photonics12050488
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ISSN: 2304-6732
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Highlights: Demonstrates directional excitation in complex topological systems using chiral sources, contributing to multi-dimensional photonic integration.
2. Topologically Protected Plasmonic Bound States in the Continuum
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Journal: Nano Letters
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Publication Date: 2024-10-23
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DOI: 10.1021/acs.nanolett.4c03636
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ISSN: 1530-6984, 1530-6992
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Highlights: Introduces novel plasmonic bound states protected by topology, potentially useful for robust nanophotonic devices.
3. Space- and Frequency-Division Multiplexing in Photonic Second-Order Topological Insulators
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Journal: Photonics Research
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Publication Date: 2024-10-01
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DOI: 10.1364/PRJ.525435
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ISSN: 2327-9125
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Highlights: Explores high-capacity photonic signal routing using second-order topological insulators, advancing multiplexing capabilities.
4. Coupling of Photonic Topological States and Their Dynamical Control Based on Liquid Crystal
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Journal: Optics Express
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Publication Date: 2024-07-01
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DOI: 10.1364/OE.527716
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ISSN: 1094-4087
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Highlights: Presents dynamic tuning of topological states using liquid crystal mediums, pointing toward reconfigurable topological photonics.
5. Tailored Triggering of High-Quality Multi-Dimensional Coupled Topological States in Valley Photonic Crystals
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Journal: Nanomaterials
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Publication Date: 2024-05-19
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DOI: 10.3390/nano14100885
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ISSN: 2079-4991
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Highlights: Focuses on engineering valley-based topological states for advanced photonic crystal applications.
6. Selective Activation of Topological Valley Corner States in C3-Symmetric Photonic Crystals
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Journal: Applied Physics Letters
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Publication Date: 2023-07-17
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DOI: 10.1063/5.0152590
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ISSN: 0003-6951, 1077-3118
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Highlights: Reports on controlled excitation of corner states in photonic systems with C3 symmetry, advancing the manipulation of topological light.
Conclusion:
Given his strong theoretical and applied research contributions, publication record in high-impact journals, and active involvement in advanced photonics projects, He Jiangle demonstrates the qualities of an outstanding early-career researcher. He is highly suitable for the Best Researcher Award, particularly in recognition of his original work in the emerging field of topological photonics and its applications in optical field manipulation.