C Photonic and Optical Materials


Organisationseinheit:
Exzellenz-Cluster Engineering of Advanced Materials

FAU Kontaktperson:
Klupp Taylor, Robin Prof.

Beschreibung:

Creation of optical materials and photonic components using micro-
or nano-structuring to tailor the optical response of dielectrics
and metals in order to create synthetic materials with different or
improved optical properties


Photonic crystal fibers (PCF) as a platform technology
for a range of new applications




The focus of Research Area C is to tailor the optical response by
micro- or nano-structuring so as to create synthetic materials with
radically different or improved optical properties. These synthetic
materials take the form of photonic crystals (λ scale features) and
metamaterials (sub-λ scale features), and are made by texturing
available substances and building composites from nanometer-sized
colloidal particles. The aim is to control the propagation of light and
its interactions with matter in new ways (e.g. extreme refractive
indices, low group velocities, high anisotropy, evanescent field
focusing, electromagnetic invisibility), improving existing devices and
realizing completely new ones (e.g. super-resolution imaging systems).
On the micro-structured scale, the emphasis will be on photonic crystal
fibers (PCF), which are distinguished by a transverse two-dimensional
“crystal” lattice of repeating units made of hollow channels that run
axially along the fiber. Compared to conventional fibers, the modal
phase index, dispersion, window of transparency, nonlinearity, and
birefringence can be tailored over wide parameter ranges. PCFs form a
“platform technology” for many new applications in the study of e.g. the
optical properties of ionic liquids, optical sensors, biomedical
devices, and laser-machining. A related goal is the optical manipulation
and characterization of nm-sized particles. Laser light will be used to
trap, manipulate, and optically characterize living cells, vesicles,
colloids, and metallic clusters, for example, both in free space and
inside hollow-core PCFs.



Zugewiesene Publikationen

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Zeltner, R., Pennetta, R., Xie, S., & Russell, P.S.J. (2018). Flying particle microlaser and temperature sensor in hollow-core photonic crystal fiber. Optics Letters, 43(7), 1479-1482. https://dx.doi.org/10.1364/OL.43.001479
Semmler, J., Pflug, L., & Stingl, M. (2018). Material optimization in transverse electromagnetic scattering applications. SIAM Journal on Scientific Computing, 40(1), B85-B109. https://dx.doi.org/10.1137/17M1127569
Hou, Y., Du, X., Scheiner, S., McMeekin, D.P., Wang, Z., Li, N.,... Brabec, C. (2017). A generic interface to reduce the efficiency-stability-cost gap of perovskite solar cells. Science, 1-9. https://dx.doi.org/10.1126/science.aao5561
Zeltner, R., Xie, S., Pennetta, R., & Russell, P.S.J. (2017). Broadband, Lensless, and Optomechanically Stabilized Coupling into Microfluidic Hollow-Core Photonic Crystal Fiber Using Glass Nanospike. ACS Photonics, 4(2), 378-383. https://dx.doi.org/10.1021/acsphotonics.6b00868
Zeltner, R., Xie, S., Pennetta, R., & Russell, P.S.J. (2017). Broadband Optomechanically Stabilized Coupling to Liquid-Filled Hollow-Core Fiber Using Silica Nanospike. In Proceedings of the Optical Trapping Applications 2017. San Diego, CA, US.
Bauer, U., Mohr, S., Döpper, T., Bachmann, P., Späth, F., Düll, F.,... Papp, C. (2017). Catalytically Triggered Energy Release from Strained Organic Molecules: The Surface Chemistry of Quadricyclane and Norbornadiene on Pt(111). Chemistry - A European Journal, 23(7), 1613-1622. https://dx.doi.org/10.1002/chem.201604443
Oßmann, B., Sarau, G., Schmitt, S.W., Holtmannspoetter, H., Christiansen, S.H., & Dicke, W. (2017). Development of an optimal filter substrate for the identification of small microplastic particles in food by micro-Raman spectroscopy. Analytical and Bioanalytical Chemistry, 409(16), 4099-4109. https://dx.doi.org/10.1007/s00216-017-0358-y
Sarau, G., Heilmann, M., Bashouti, M., Latzel, M., Tessarek, C., & Christiansen, S. (2017). Efficient Nitrogen Doping of Single-Layer Graphene Accompanied by Negligible Defect Generation for Integration into Hybrid Semiconductor Heterostructures. ACS Applied Materials and Interfaces, 9(11), 10003-10011. https://dx.doi.org/10.1021/acsami.7b00067
Zoheidi, L., Panradl, C., Rauh, C., & Delgado, A. (2017). Experimental investigation of the protein foam flow structure in horizontal channels:Flow regime and corresponding bubble size distribution. Journal of Food Process Engineering, 40(6), e12563. https://dx.doi.org/10.1111/jfpe.12563
Konnerth, C.-G., Braig, V., Schmidt, J., Lee, G., Peukert, W., & Ito, A. (2017). Formation of Mefenamic Acid Nanocrystals with Improved Dissolution Characteristics. Chemie Ingenieur Technik, 89(89), 1060-1071. https://dx.doi.org/10.1002/cite.201600190

Zuletzt aktualisiert 2019-26-03 um 14:29