157 156 Principal Scientist Profiles Adriana Szeghalmi Adriana Szeghalmi Principal Scientist Profiles EMMY NOETHER GROUP LEADER FOR ATOMIC LAYER DEPOSITION OF OPTICAL COATINGS, INSTITUTE OF APPLIED PHYSICS Dr. Adriana Szeghalmi is head of the Emmy Noether research group Atomic Layer Deposition of Optical Coatings and head of the ATTRACT research group Atomic Layer Deposition for Optics at the Fraunhofer Institute for Applied Optics and Precision Engineering (IOF) Jena. ADRIANA SZEGHALMI RESEARCH AREAS The Atomic Layer Deposition Group aims to establish this technology for the development of novel and improved optical elements. We currently focus on devel-oping atomic layer deposited coatings for: • Low and high refractive indices • Porous materials • Advanced nanostructuring technologies • Interference coatings • Functional coatings for diffractive optical elements • Space & laser technology, spectrometry, UV-VIS, DUV, EUV, BEUV, x-ray optics • Understanding chemical reactions during nucleation and film growth TEACHING FIELDS Dr. Szeghalmi currently mentors three doctoral students and a postdoctoral scientist. Graduate students interested in handson experience in optical coatings and optical design are welcome to join the group. A course on inorganic and organic materials in photonics is in preparation. RESEARCH METHODS The ALD facility led by Dr. Szeghalmi has two plasmaenhanced atomic layer deposition reactors at hand. Both are located in a clean room environment and are equipped with in situ monitoring techniques for experimental characterization by means of spectroscopic ellipsometry in the 245 nm to 1700 nm spectral range. The equipment comprises: • OpAL PEALD, Oxford Plasma Technologies • Sunale R200, Picosun Oy • J. A. Woollam spectroscopic ellipsometer RECENT RESEARCH RESULTS Atomic layer deposition (ALD) is a cyclic, self-limiting chemical deposition technique. The thickness of ALD films is controlled with sub-nanometer precision by the number of ALD cycles. The films manifest high uniformity and low roughness. Most importantly, conformal coating can be achieved on nanostructured materials. A wide range of materials, including oxides, nitrides, fluorides, sulfides, metals and hybrid organic-inorganic composites, can be deposited via the ALD and molecular layer deposition (MLD) techniques. The above-mentioned materials find numerous applications in the fields of photovoltaics, electronics, catalysis, biotechnology, display technology, and photonics. High and low refractive index dielectrics are essential for refractive and diffractive optics. High optical quality and excellent reproducibility have been achieved for SiO2, Al2O3, HfO2, Ta2O5, and TiO2 coatings. The deposition of titanium dioxide (TiO2) using/via ALD was thoroughly investigated [1] and the optical properties are depicted in Figure 1. Encapsulated gratings show higher efficiency levels than do binary gratings. An improved encapsulation process was developed based on atomic layer deposition and microstructuring. A detailed description of the process is published in [2]. Figure 2 shows a cross-sectioned FIBSEM image of an encapsulated grating designed for TM-polarized light at wavelengths of 1000…1064 nm. The first SiO2 layer on top of the grating is realized via/using ALD deposition to ensure a high degree of chem-ical bonding to the substrate. Fortunately, no boundary is visible between the grating top and the encapsulation layer. The Ta2O5 and SiO2 layers serve as antireflection coatings made via PVD. The system is in accordance with the ISO:9211-4:2007-03 norm pertaining to the adhesive strength of the layers. The grating efficiency is 97.5% at 1030 nm. The encapsulated grating has a much higher efficiency (up to 8%) than conventional binary gratings in the given spectral range. EMBEDDED GRATING Another approach to enhance the diffraction efficiency of transmission gratings is by embedding silica gratings into a high refractive index material. During this study, the TiO2/Al2O3 nanolaminate has been applied to functionalize a binary-fused silica grating for highly efficient transmittance gratings between 1000-1060 nm wavelengths which are designed for TM or TE-polarized light. Figure 3 depicts a FIB-cut SEM cross-section image of an embedded grating designed for TM-polarized light. The nanolaminate‘s fine structure can be viewed in the cross-section image, and proves that a pinhole-free embedment is possible via ALD. This is essential due to the fact that even tiny air pockets will drastically reduce the grating‘s efficiency. The transmission efficiency at the -1st diffraction order is 95% at the 1030 nm wavelength, being confirmed using RCWA simulations with the real grating parameter. The grating‘s period of 543 nm is nearly half of the incident wavelength for very high dispersion of fs-pulses using the chirped pulse amplification method (CPA). Figure 1: Dispersion of TiO2 layers deposited (a) via plasma enhanced atomic layer deposition (PEALD), and (b) thermal atomic layer deposition (thermal ALD) at different deposition conditions. The plasma-enhanced atomic layer deposition of TiO2 was performed at different oxygen gas-flow rates, plasma powers and deposition temperatures T S . Thermal depositions were carried out at deposition temperatures of 120 °C, 150 °C and 200 °C. Refractive indices are based on the Cody-Lorentz model, chosen for its suitability to the obtained ellipsometric data. Figure 2. A FIB-cut SEM crosssection image of an encapsulated grating. The three layer system on the grating is only 700 nm thick for use as an antireflection coating. [1] Ratzsch et al., Nanotechnol., 26, 11 (2015). [2] Ratzsch et al., Opt. Express, 23, 17955 (2015). Contact: Phone: + 49 3641 9-47859 Email: a.szeghalmi@uni-jena.de, adriana.szeghalmi@iof.fraunhofer.de
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