Volume 4, Issue 2 (Suppl)

J Laser Opt Photonics, an open access journal

ISSN: 2469-410X

Page 43

conference

series

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JOINT EVENT

July 31- August 02, 2017 Milan, Italy

&

6

th

International Conference on Photonics

7

th

International Conference on Laser Optics

III-V nanowire arrays as a platform for photovoltaics, solid state lighting and electronics

I

n this presentation, the physical principles of semiconductor nanowire arrays are discussed, with a focus on applications

for photovoltaics and solid state lighting. Both of these fields are pivotal for green photonics technologies. As analysis tools,

specific physics-based numerical models for nanophotonics and nanoelectronics have been developed, which will be discussed.

In particular, the three-dimensional nature of a wire array, including the substrate and the free space on top is included in the

study. For the optical extraction efficiency of an LED, absorption of electromagnetic energy in the contacts and the active layers

themselves, as well as re-emission (photon-recycling) are investigated. The latter is an effect that couples the electronic and the

optical system. In addition, the optical density of states is analyzed and its impact on the extraction efficiency is shown. Finally,

the total electro-optical efficiency of a nanowire array LED emitting at 400nm is presented and compared to conventional

efficient thin-film LEDs. It is shown that the efficiency droop commonly observed in III-nitride based LEDs can be shifted to

high operating currents. For the nanowire array solar cell, a detailed electromagnetic and electronic analysis is presented, from

which fundamental rules in terms of materials choice and wire geometry will be derived. It shows that low density regular

III-V nanowire arrays can reach absorptivities identical to bulk cells, with the advantage of substrate flexibility, low material

consumption, and improved strain engineering for multi-junction cells. As outlook, the integration of III-V nanowire arrays

for electronic and optical functional devices will be discussed and some applications are shown.

Figure1:

Optical generation rate in an InGaN/GaN core-shell nanowire solar cell

Biography

Bernd Witzigmann received his PhD degree (with honors) in Technical Sciences from the ETH Zürich, Switzerland, in 2000. He then joined Bell Laboratories, Murray Hill,

NJ, as a Member of Technical Staff. In 2004, he was appointed as Assistant Professor at ETH Zurich in Switzerland. Since 2008, he was Professor at University of Kassel,

Germany, and Co-Director of the Centre of Interdisciplinary Nanoscience and Technology. He is author/co-author of more than 180 journal and conference publications,

Chairman of a SPIE Photonics West conference, and has been Editor of several journals. He is a Senior Member of the IEEE and SPIE and Co-Director of the Nanocenter

CINSaT at Kassel University.

bernd.witzigmann@uni-kassel.de

Bernd Witzigmann

1

Kassel University, Germany

2

CINSaT, Germany

Bernd Witzigmann, J Laser Opt Photonics 2017, 4:2(Suppl)

DOI: 10.4172/2469-410X-C1-010