Open AccessHollow core and other infrared waveguides for instrumentation in intense radiation environments.
Author(s) -
Jonathan D. Weiss
Publication year - 2007
Publication title -
osti oai (u.s. department of energy office of scientific and technical information)
Language(s) - English
Resource type - Reports
DOI - 10.2172/1029799
Subject(s) - opacity , infrared , radiation , context (archaeology) , instrumentation (computer programming) , neutron , optical fiber , core (optical fiber) , optics , materials science , infrared spectroscopy , optoelectronics , physics , nuclear physics , computer science , geology , paleontology , operating system , quantum mechanics
The purpose of this LDRD was to study the effect of steady-state neutron and gamma irradiation on the transmission of waveguides designed to operate well in the near- or mid-IR region of the electromagnetic spectrum. In this context, near-IR refers to the region between 1.3 {mu}m and about 2.4 {mu}m, and mid-IR between 3.0 {mu}m and 4.5 {mu}m. Such radiation environments could exist in nuclear power plants or nuclear weapons. Pulsed and steady-state radiation effects had been extensively studied on silica-based optical fibers because they have been the most readily available, most widely used in communications and sensing, and the least expensive. However, silica-based fibers do not transmit well beyond about 1.8 {mu}m and they are virtually opaque in the mid-IR. The mid-IR, as defined above, and beyond, is where vibrational spectroscopy is carried out. This type of sensing is one important application of infrared optical fibers
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