Toward high laser power beam manipulation with nanophotonic materials: evaluating thin film damage performance.

Nanophotonic materials enable unprecedented control of light-matter interactions, including the ability to dynamically steer or shape wavefronts. Consequently, nanophotonic systems such as metasurfaces have been touted as promising candidates for free-space optical communications, directed energy and additive manufacturing, which currently rely on slow mechanical scanners or electro-optical components for beam steering and shaping. However, such applications necessitate the ability to support high laser irradiances (> kW/cm2) and systematic studies on the high-power laser damage performance of nanophotonic materials and designs are sparse. Here, we experimentally investigate the pulsed laser-induced damage performance (at λ ∼ 1 µm) of model nanophotonic thin films including gold, indium tin oxide, and refractory materials such as titanium nitride and titanium oxynitride. We also model the spatio-thermal dissipation dynamics upon single-pulse illumination by anchoring experimental laser damage thresholds. Our findings show that gold exhibits the best laser damage resistance, but we argue that alternative materials such as transparent conducting oxides could be optimized to balance the tradeoff between damage resistance and optical tunability, which is critical for the design of thermally robust nanophotonic systems. We also discuss damage mitigation and ruggedization strategies for future device-scale studies and applications requiring high power beam manipulation.

[1]  Liping Peng,et al.  Temperature dependence of initial deformation and cracks of indium tin oxide film by quasi-continuous-wave laser irradiations , 2020 .

[2]  Harry A. Atwater,et al.  Electro-Optically Tunable Multifunctional Metasurfaces. , 2020, ACS nano.

[3]  V. Shalaev,et al.  Broadband Ultrafast Dynamics of Refractory Metals: TiN and ZrN , 2020, Advanced Optical Materials.

[4]  Houtong Chen,et al.  Highly Plasmonic Titanium Nitride by Room-Temperature Sputtering , 2019, Scientific Reports.

[5]  Sourabh K. Saha,et al.  Scalable submicrometer additive manufacturing , 2019, Science.

[6]  S. Falabella,et al.  A Survey of Transparent Conducting Films and Optoelectrical Materials for High Optical Power Applications , 2019, physica status solidi (a).

[7]  Wen-Hui Cheng,et al.  Dynamic beam steering with all-dielectric electro-optic III–V multiple-quantum-well metasurfaces , 2019, Nature Communications.

[8]  S. Gwo,et al.  Titanium Nitride Epitaxial Films as a Plasmonic Material Platform: Alternative to Gold , 2019, ACS Photonics.

[9]  Jianda Shao,et al.  Laser damage characteristics of indium-tin-oxide film and polyimide film , 2019, Infrared Physics & Technology.

[10]  Pin Chieh Wu,et al.  Phase Modulation with Electrically Tunable Vanadium Dioxide Phase-Change Metasurfaces. , 2019, Nano letters.

[11]  Vladimir M. Shalaev,et al.  Spatiotemporal light control with active metasurfaces , 2019, Science.

[12]  Sergey I. Bozhevolnyi,et al.  Dynamic Metasurfaces Using Phase‐Change Chalcogenides , 2019, Advanced Optical Materials.

[13]  P. McIntyre,et al.  Dynamic thermal emission control with InAs-based plasmonic metasurfaces , 2018, Science Advances.

[14]  V. Pruneri,et al.  Tunable plasmons in ultrathin metal films , 2018, Nature Photonics.

[15]  S. Maier,et al.  Temperature stability of thin film refractory plasmonic materials. , 2018, Optics express.

[16]  Hongwei Liu,et al.  Metamaterials based on the phase transition of VO2 , 2018, Nanotechnology.

[17]  T. Nagao,et al.  Fabrication of Highly Metallic TiN Films by Pulsed Laser Deposition Method for Plasmonic Applications , 2018 .

[18]  Federico Capasso,et al.  Dynamic metasurface lens based on MEMS technology , 2017, 1712.03616.

[19]  Yury V Stebunov,et al.  Optical constants and structural properties of thin gold films. , 2017, Optics express.

[20]  J. Bude,et al.  Thermally ruggedized ITO transparent electrode films for high power optoelectronics. , 2017, Optics express.

[21]  Daniel J. Heath,et al.  Digital micromirror devices and femtosecond laser pulses for rapid laser micromachining , 2017 .

[22]  Daniel J. Riggs,et al.  Light sources for high-volume manufacturing EUV lithography: technology, performance, and power scaling , 2017 .

[23]  Gabe Guss,et al.  Diode-based additive manufacturing of metals using an optically-addressable light valve. , 2017, Optics express.

[24]  S. Maier,et al.  Titanium Oxynitride Thin Films with Tunable Double Epsilon-Near-Zero Behavior for Nanophotonic Applications. , 2017, ACS applied materials & interfaces.

[25]  N. Melosh,et al.  Temperature-dependent optical properties of titanium nitride , 2017 .

[26]  A. Kildishev,et al.  Temperature-Dependent Optical Properties of Plasmonic Titanium Nitride Thin Films , 2017, 1702.03053.

[27]  Jacob Scheuer,et al.  Metasurfaces-based holography and beam shaping: engineering the phase profile of light , 2017 .

[28]  Christine M. Zgrabik,et al.  Nonlinear Refractory Plasmonics with Titanium Nitride Nanoantennas. , 2016, Nano letters.

[29]  M. Alkaisi,et al.  Effects of film thickness and sputtering power on properties of ITO thin films deposited by RF magnetron sputtering without oxygen , 2016, Journal of Materials Science: Materials in Electronics.

[30]  A. Kildishev,et al.  Temperature-dependent optical properties of gold thin films , 2016, 1604.00064.

[31]  J. Teng,et al.  Optically reconfigurable metasurfaces and photonic devices based on phase change materials , 2015, Nature Photonics.

[32]  Christine M. Zgrabik,et al.  Optimization of sputtered titanium nitride as a tunable metal for plasmonic applications , 2015 .

[33]  D. Tsai,et al.  Gate-Tunable Conducting Oxide Metasurfaces. , 2015, Nano letters.

[34]  Igal Brener,et al.  Active tuning of all-dielectric metasurfaces. , 2015, ACS nano.

[35]  Pierre Berini,et al.  Plasmonic nanostructured metal-oxide-semiconductor reflection modulators. , 2015, Nano letters.

[36]  A. Kildishev,et al.  Refractory Plasmonics with Titanium Nitride: Broadband Metamaterial Absorber , 2014, Advanced materials.

[37]  J. Khurgin How to deal with the loss in plasmonics and metamaterials. , 2014, Nature nanotechnology.

[38]  N. Yu,et al.  Flat optics with designer metasurfaces. , 2014, Nature materials.

[39]  V. Shalaev,et al.  Alternative Plasmonic Materials: Beyond Gold and Silver , 2013, Advanced materials.

[40]  J. Khurgin,et al.  Reflecting upon the losses in plasmonics and metamaterials , 2012 .

[41]  M. Kafesaki,et al.  A comparison of graphene, superconductors and metals as conductors for metamaterials and plasmonics , 2012, Nature Photonics.

[42]  Dayong Zhang,et al.  Thickness effect on laser-induced-damage threshold of indium-tin oxide films at 1064 nm , 2011 .

[43]  Viktor A. Podolskiy,et al.  Transparent conductive oxides: Plasmonic materials for telecom wavelengths , 2011 .

[44]  H. Atwater,et al.  Unity-order index change in transparent conducting oxides at visible frequencies. , 2010, Nano letters (Print).

[45]  Jacob B. Khurgin,et al.  In search of the elusive lossless metal , 2010 .

[46]  G. Baffou,et al.  Mapping heat origin in plasmonic structures. , 2010, Physical review letters.

[47]  Yusuf Selamet,et al.  High quality ITO thin films grown by dc and RF sputtering without oxygen , 2010 .

[48]  Kai Starke,et al.  Laser damage thresholds of optical coatings , 2009 .

[49]  Edward A. Watson,et al.  A Review of Phased Array Steering for Narrow-Band Electrooptical Systems , 2009, Proceedings of the IEEE.

[50]  T. Yagi,et al.  Thermal transport properties of polycrystalline tin-doped indium oxide films , 2009 .

[51]  Neil Savage,et al.  Digital spatial light modulators , 2009 .

[52]  Randolph Kirchain,et al.  A roadmap for nanophotonics , 2007 .

[53]  Simon J. Henley,et al.  Pulsed-laser-induced nanoscale island formation in thin metal-on-oxide films , 2005 .

[54]  Muyu Zhao,et al.  Size-dependent melting point of noble metals , 2003 .

[55]  Claude Amra,et al.  Laser-induced damage of materials in bulk, thin-film, and liquid forms. , 2002, Applied optics.

[56]  E. H. Sondheimer,et al.  The mean free path of electrons in metals , 2001 .

[57]  Brent C. Stuart,et al.  Optical ablation by high-power short-pulse lasers , 1996 .

[58]  Perry,et al.  Laser-induced damage in dielectrics with nanosecond to subpicosecond pulses. , 1995, Physical review letters.

[59]  Arthur H. Guenther,et al.  The role of thermal conductivity in the pulsed laser damage sensitivity of optical thin films , 1988 .

[60]  Arthur H. Guenther,et al.  The Role Of Thermal Conductivity In The Pulsed Laser Damage Sensitivity Of Optical Thin Films+ , 1988, Photonics West - Lasers and Applications in Science and Engineering.

[61]  Michael F. Becker,et al.  Laser-induced damage on single-crystal metal surfaces , 1988 .

[62]  P. Woias,et al.  Thermoelectric properties of Au and Ti nanofilms, characterized with a novel measurement platform , 2019, Materials Today: Proceedings.

[63]  J. Bude,et al.  Optical damage performance of conductive widegap semiconductors: spatial, temporal, and lifetime modeling , 2017 .

[64]  M. Schmid Principles Of Optics Electromagnetic Theory Of Propagation Interference And Diffraction Of Light , 2016 .

[65]  Peter Nordlander,et al.  Plasmon-induced hot carrier science and technology. , 2015, Nature nanotechnology.

[66]  Roger M. Wood,et al.  Selected papers on laser damage in optical materials , 1990 .