Resistance of Coated and Uncoated IR Windows to Seawater Corrosion.

Germanium and chalcogenide glass specimens were submerged to a 35-foot depth in San Diego Bay for 4 months and the deterioration of their surfaces noted. Some of the specimens were bare, some were protected with a single-layer anti-reflective (AR) IR coating, the remainder were coated with either po...

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Bibliographic Details
Main Authors: Stachiw ,J D, Bertic,S L
Other Authors: NAVAL OCEAN SYSTEMS CENTER SAN DIEGO CA
Format: Text
Language:English
Published: 1979
Subjects:
Coatings
Colorants and Finishes
Submarine Engineering
Infrared Detection and Detectors
*SUBMARINE EQUIPMENT
*CORROSION INHIBITION
*PROTECTIVE COATINGS
*ANTIREFLECTION COATINGS
*INFRARED WINDOWS
CORROSION
GLASS
ENVIRONMENTAL TESTS
OPTICAL COATINGS
GERMANIUM
SUBMARINES
SEA WATER
CHALCOGENS
PLASTIC COATINGS
Exoctic materials 40104
Arctic
Online Access:http://www.dtic.mil/docs/citations/ADA076297
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA076297
id ftdtic:ADA076297
record_format openpolar
spelling ftdtic:ADA076297 2023-05-15T15:13:35+02:00 Resistance of Coated and Uncoated IR Windows to Seawater Corrosion. Stachiw ,J D Bertic,S L NAVAL OCEAN SYSTEMS CENTER SAN DIEGO CA 1979-08-15 text/html http://www.dtic.mil/docs/citations/ADA076297 http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA076297 en eng http://www.dtic.mil/docs/citations/ADA076297 APPROVED FOR PUBLIC RELEASE DTIC AND NTIS Coatings Colorants and Finishes Submarine Engineering Infrared Detection and Detectors *SUBMARINE EQUIPMENT *CORROSION INHIBITION *PROTECTIVE COATINGS *ANTIREFLECTION COATINGS *INFRARED WINDOWS CORROSION GLASS ENVIRONMENTAL TESTS OPTICAL COATINGS GERMANIUM SUBMARINES SEA WATER CHALCOGENS PLASTIC COATINGS Exoctic materials 40104 Text 1979 ftdtic 2016-02-20T17:05:57Z Germanium and chalcogenide glass specimens were submerged to a 35-foot depth in San Diego Bay for 4 months and the deterioration of their surfaces noted. Some of the specimens were bare, some were protected with a single-layer anti-reflective (AR) IR coating, the remainder were coated with either polyolefine, polyethylene, or polypropylene plastic surcoat. To simulate different operational scenarios to which a submarine-mounted IR window may be subjected, some of the specimens were exposed to natural water circulation, others to water velocities of 6 feet per second. Additionally, some of the submerged specimens were heated by an electric current to simulate de-icing procedures in an arctic environment. Unprotected germanium was found to corrode rapidly while chalcogenide AMTIR-1 glass exhibited excellent corrosion resistance. All plastic surcoats failed by separation from the specimens due to presence of pinholes and water permeability. Anti-reflective coatings deteriorated also, but the transmission of the best single layer AR coating tested (Exotic Materials No. 40104) decreased only five percent, even though presence of pinholes in the coating generated many shallow ( 0.010 inch) corrosion craters in the surfaces of the germanium specimens. Passage of electric current through germanium accelerated the rate of corrosion; one hour of current flow produced more corrosion to the wetted window surface than 8000 hours without electric current. Next phase of testing will cover not only improved single layer, but also durable multilayer AR coatings that promise to extend the life of germanium windows in seawater to 12 months. (Author) Text Arctic Defense Technical Information Center: DTIC Technical Reports database Arctic
institution Open Polar
collection Defense Technical Information Center: DTIC Technical Reports database
op_collection_id ftdtic
language English
topic Coatings
Colorants and Finishes
Submarine Engineering
Infrared Detection and Detectors
*SUBMARINE EQUIPMENT
*CORROSION INHIBITION
*PROTECTIVE COATINGS
*ANTIREFLECTION COATINGS
*INFRARED WINDOWS
CORROSION
GLASS
ENVIRONMENTAL TESTS
OPTICAL COATINGS
GERMANIUM
SUBMARINES
SEA WATER
CHALCOGENS
PLASTIC COATINGS
Exoctic materials 40104
spellingShingle Coatings
Colorants and Finishes
Submarine Engineering
Infrared Detection and Detectors
*SUBMARINE EQUIPMENT
*CORROSION INHIBITION
*PROTECTIVE COATINGS
*ANTIREFLECTION COATINGS
*INFRARED WINDOWS
CORROSION
GLASS
ENVIRONMENTAL TESTS
OPTICAL COATINGS
GERMANIUM
SUBMARINES
SEA WATER
CHALCOGENS
PLASTIC COATINGS
Exoctic materials 40104
Stachiw ,J D
Bertic,S L
Resistance of Coated and Uncoated IR Windows to Seawater Corrosion.
topic_facet Coatings
Colorants and Finishes
Submarine Engineering
Infrared Detection and Detectors
*SUBMARINE EQUIPMENT
*CORROSION INHIBITION
*PROTECTIVE COATINGS
*ANTIREFLECTION COATINGS
*INFRARED WINDOWS
CORROSION
GLASS
ENVIRONMENTAL TESTS
OPTICAL COATINGS
GERMANIUM
SUBMARINES
SEA WATER
CHALCOGENS
PLASTIC COATINGS
Exoctic materials 40104
description Germanium and chalcogenide glass specimens were submerged to a 35-foot depth in San Diego Bay for 4 months and the deterioration of their surfaces noted. Some of the specimens were bare, some were protected with a single-layer anti-reflective (AR) IR coating, the remainder were coated with either polyolefine, polyethylene, or polypropylene plastic surcoat. To simulate different operational scenarios to which a submarine-mounted IR window may be subjected, some of the specimens were exposed to natural water circulation, others to water velocities of 6 feet per second. Additionally, some of the submerged specimens were heated by an electric current to simulate de-icing procedures in an arctic environment. Unprotected germanium was found to corrode rapidly while chalcogenide AMTIR-1 glass exhibited excellent corrosion resistance. All plastic surcoats failed by separation from the specimens due to presence of pinholes and water permeability. Anti-reflective coatings deteriorated also, but the transmission of the best single layer AR coating tested (Exotic Materials No. 40104) decreased only five percent, even though presence of pinholes in the coating generated many shallow ( 0.010 inch) corrosion craters in the surfaces of the germanium specimens. Passage of electric current through germanium accelerated the rate of corrosion; one hour of current flow produced more corrosion to the wetted window surface than 8000 hours without electric current. Next phase of testing will cover not only improved single layer, but also durable multilayer AR coatings that promise to extend the life of germanium windows in seawater to 12 months. (Author)
author2 NAVAL OCEAN SYSTEMS CENTER SAN DIEGO CA
format Text
author Stachiw ,J D
Bertic,S L
author_facet Stachiw ,J D
Bertic,S L
author_sort Stachiw ,J D
title Resistance of Coated and Uncoated IR Windows to Seawater Corrosion.
title_short Resistance of Coated and Uncoated IR Windows to Seawater Corrosion.
title_full Resistance of Coated and Uncoated IR Windows to Seawater Corrosion.
title_fullStr Resistance of Coated and Uncoated IR Windows to Seawater Corrosion.
title_full_unstemmed Resistance of Coated and Uncoated IR Windows to Seawater Corrosion.
title_sort resistance of coated and uncoated ir windows to seawater corrosion.
publishDate 1979
url http://www.dtic.mil/docs/citations/ADA076297
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA076297
geographic Arctic
geographic_facet Arctic
genre Arctic
genre_facet Arctic
op_source DTIC AND NTIS
op_relation http://www.dtic.mil/docs/citations/ADA076297
op_rights APPROVED FOR PUBLIC RELEASE
_version_ 1766344120921489408

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