Prof. Saulius Juodkazis
Deputy Director & Professor at Swinburne Univ of Technology
SPIE Involvement:
Fellow status | Conference Program Committee | Symposium Chair | Conference Chair | Journal Editorial Board Member | Author | Editor | Instructor
Area of Expertise:
Plasmonics and nanophotonics , Laser tweezers , Ablation, laser nano-/micro-fabrication , Solar energy conversion , Photo-polymerization, Photonic crystals , Structuring of materials by dielecric breakdown
Profile Summary

Professor Saulius Juodkazis received his doctorate in experimental physics and material science jointly from Vilnius University (Lithuania) and Lyon-I University (France) in '97. From then on, he held previous faculty positions at the University of Tokushima (lecturer and assistant professor) and Hokkaido (associate professor) in Japan. He has contributed to development of a three-dimensional femtosecond laser micro-fabrication for optofluidic, optical memory, and photonic crystal applications. He is author of more than 320 peer-reviewed journal papers, reviews, and several book chapters.

His current research is focused on applying principles of plasmonic light-field enhancement and its spectral control for applications in sensing, solid-state lighting, and solar energy conversion.

S. Juodkazis is a Fellow of OSA and SPIE. He organised series of Australian-Japanese student research conferences, promotes domestic and international student research projects and initiated the first Australian joint SPIE-OSA student chapter in 2013.
Publications (87)

Proc. SPIE. 10456, Nanophotonics Australasia 2017
KEYWORDS: Refractive index, Gaussian beams, Dielectrics, Silicon, Wavefronts, Terahertz radiation, Transmittance, Beam shaping, Reactive ion etching, Dielectric polarization

Proc. SPIE. 10456, Nanophotonics Australasia 2017
KEYWORDS: Electronics, Light emitting diodes, LED lighting, Agriculture, Spectroscopy, Lamps, Light sources and illumination, RGB color model

Proc. SPIE. 10456, Nanophotonics Australasia 2017
KEYWORDS: Plasmonics, Nanostructures, Glasses, Silver, Surface enhanced Raman spectroscopy, Raman spectroscopy, Sapphire, Raman scattering

SPIE Journal Paper | September 15, 2017
OE Vol. 56 Issue 09
KEYWORDS: Glasses, Lab on a chip, Femtosecond phenomena, Microfabrication, Additive manufacturing, Microfluidics, Optical filters, Laser ablation, Particles, Image filtering

Proc. SPIE. 10339, Pacific Rim Laser Damage 2017: Optical Materials for High-Power Lasers
KEYWORDS: Optical components, Glasses, Laser induced damage, Laser applications, 3D printing, Nonimpact printing, Laser optics, Light-matter interactions

PROCEEDINGS ARTICLE | February 20, 2017
Proc. SPIE. 10115, Advanced Fabrication Technologies for Micro/Nano Optics and Photonics X
KEYWORDS: Lithography, Photodetectors, Nanostructures, Crystals, Photonic crystals, Colorimetry, Wave propagation, Infrared radiation, Infrared photography, Infrared detection, Nanolithography, Photonic microstructures, Photonic nanostructures, Absorption

Showing 5 of 87 publications
Conference Committee Involvement (15)
Advanced Fabrication Technologies for Micro/Nano Optics and Photonics XI
28 January 2018 | San Francisco, California, United States
SPIE Nanophotonics Australasia
10 December 2017 | Melbourne, Australia
Advanced Fabrication Technologies for Micro/Nano Optics and Photonics X
29 January 2017 | San Francisco, California, United States
Advanced Fabrication Technologies for Micro/Nano Optics and Photonics IX
14 February 2016 | San Francisco, California, United States
SPIE Micro+Nano Materials, Devices, and Systems
7 December 2015 | Sydney, New South Wales, Australia
Showing 5 of 15 published special sections
Course Instructor
SC1226: 3D Nano-/Micro Printing
This course explains basic experimental and theoretical principles of nanoscale 3D fabrication/printing and characterisation of nanoscale properties by light scattering and absorption using nano-sharp tip. 3D nanofabrication has become an important tool for fabrication of photonic circuitry and sensors. This course will be overviewing the current existing methods of 3D laser fabrication of photonic wire bonding and interconnects, holographic larger area patterning, focused ion and electron lithography, and thermal scanning tip writing. Students and researchers will gain better understanding of scaling properties and fabrication throughput of nanoscale devices based on modern 3D nanofabrication tools. Also, characterisation of nanoscale structures and patterns with nanoscale imaging tools will be introduced based on most recent commercial equipment.
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