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Three dimensional chalcogenide photonic crystals created by direct laser writing and chemical vapor deposition

Three dimensional chalcogenide photonic crystals created by direct laser writing and chemical vapor deposition
Three dimensional chalcogenide photonic crystals created by direct laser writing and chemical vapor deposition
Rod connected diamond (RCD) [1], which is known to exhibit the largest full PBGs among all designs [2] with the same index contrast, has been investigated but remains a significant challenge to create [3]. Here, we use Direct Laser Writing [4] (DLW) method to fabricate polymeric (n = 1.52) RCD templates and characterize its band structure via an angular-resolved spectroscopy. High refractive index photoresist and/or materials will be identified. Here, we intend to begin with chalcogenide (n = 2.4:1) backfilling via chemical vapor deposition technique [5] to realize the full photonic bandgap photonic crystals.
etc...
Chen, Lifeng
5e67c8cc-4317-4ceb-9d78-74cbc4beb8cd
Zheng, Xu
e496730c-6b52-49ca-8142-933ce5df5159
Taverne, Mike P.C.
6444e2cd-5d52-43a7-83b6-2e72f922501d
Ho, Y.-L. Daniel
945e3431-b334-4d98-858f-c3fae452640f
Huang, Chung-Che
825f7447-6d02-48f6-b95a-fa33da71f106
Hewak, Daniel
87c80070-c101-4f7a-914f-4cc3131e3db0
Rarity, John G.
f7e3ab11-2a7c-4242-bf27-93f1adb5420f
Chen, Lifeng
5e67c8cc-4317-4ceb-9d78-74cbc4beb8cd
Zheng, Xu
e496730c-6b52-49ca-8142-933ce5df5159
Taverne, Mike P.C.
6444e2cd-5d52-43a7-83b6-2e72f922501d
Ho, Y.-L. Daniel
945e3431-b334-4d98-858f-c3fae452640f
Huang, Chung-Che
825f7447-6d02-48f6-b95a-fa33da71f106
Hewak, Daniel
87c80070-c101-4f7a-914f-4cc3131e3db0
Rarity, John G.
f7e3ab11-2a7c-4242-bf27-93f1adb5420f

Chen, Lifeng, Zheng, Xu, Taverne, Mike P.C., Ho, Y.-L. Daniel, Huang, Chung-Che, Hewak, Daniel and Rarity, John G. (2015) Three dimensional chalcogenide photonic crystals created by direct laser writing and chemical vapor deposition. Glass Reflections: Glass in the Year of Light, United Kingdom. 07 - 09 Sep 2015.

Record type: Conference or Workshop Item (Other)

Abstract

Rod connected diamond (RCD) [1], which is known to exhibit the largest full PBGs among all designs [2] with the same index contrast, has been investigated but remains a significant challenge to create [3]. Here, we use Direct Laser Writing [4] (DLW) method to fabricate polymeric (n = 1.52) RCD templates and characterize its band structure via an angular-resolved spectroscopy. High refractive index photoresist and/or materials will be identified. Here, we intend to begin with chalcogenide (n = 2.4:1) backfilling via chemical vapor deposition technique [5] to realize the full photonic bandgap photonic crystals.
etc...

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More information

e-pub ahead of print date: 9 September 2015
Venue - Dates: Glass Reflections: Glass in the Year of Light, United Kingdom, 2015-09-07 - 2015-09-09
Organisations: Optoelectronics Research Centre

Identifiers

Local EPrints ID: 381276
URI: https://eprints.soton.ac.uk/id/eprint/381276
PURE UUID: 889b78cc-1ff0-4828-a576-81d42cb5390f
ORCID for Chung-Che Huang: ORCID iD orcid.org/0000-0003-3471-2463
ORCID for Daniel Hewak: ORCID iD orcid.org/0000-0002-2093-5773

Catalogue record

Date deposited: 01 Oct 2015 10:26
Last modified: 06 Jun 2018 13:08

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