Spectrometer
Abstract
Spectrometers and methods for determining the presence or absence of a material in proximity to and/or combined with another material are provided. In one particular example, a spectrometer is provided that includes a light source, a detector and an optical system. In this implementation, the light source is configured to provide an excitation incident beam. The detector is configured to detect a spectroscopy signal. The optical system is configured to direct the excitation incident beam toward a sample at a non-zero angle from a zero-angle reference. The optical system is further configured to receive a spectroscopy signal from the sample and provide the spectroscopy signal to the detector. The detector is configured to remove a spectral interference component of the spectroscopy signal.
Claims
exact text as granted — not AI-modified1 . A spectrometer comprising:
a light source adapted to provide an excitation incident beam; a detector adapted to detect a spectroscopy signal; and an optical system adapted to direct the excitation incident beam toward a sample at a non-zero angle from a zero-angle reference, receive a spectroscopy signal from the sample and provide the spectroscopy signal to the detector, wherein the detector is adapted to remove a spectral interference component of the spectroscopy signal.
2 . The spectrometer of claim 1 wherein the detector is adapted to remove the spectral interference component through spectral subtraction.
3 . The spectrometer of claim 1 wherein the detector is adapted to remove the spectral interference component through spectral subtraction of at least one known component.
4 . The spectrometer of claim 1 wherein the detector is adapted to remove the spectral interference component through spectral subtraction of at least one known component stored in a library.
5 . The spectrometer of claim 4 wherein the library stores spectral interference components of a plurality of known materials.
6 . The spectrometer of claim 4 wherein the plurality of known materials includes a plurality of containers.
7 . The spectrometer of claim 4 wherein the plurality of known materials includes a plurality of plastic containers.
8 . The spectrometer of claim 1 wherein the detector is adapted to receive a plurality of spectroscopy signals from the sample.
9 . The spectrometer of claim 8 wherein the plurality of spectroscopy signals correspond to a plurality of incident beams directed toward the sample at different angles and/or offsets from a zero-axis line.
10 . A spectrometer comprising:
a light source adapted to provide an excitation incident beam; a detector adapted to detect a spectroscopy signal; and an optical system adapted to direct the excitation incident beam toward a sample at a non-zero angle from a zero-axis reference, receive a spectroscopy signal from the sample and provide the spectroscopy signal to the detector, wherein the detector is adapted to compare a plurality of spectroscopy signals corresponding to a plurality of incident beams directed toward the sample from a plurality of different non-zero angles and/or offsets from the zero-axis reference to identify at least one component of the spectroscopy signal corresponding to the sample.
11 . The spectrometer of claim 10 wherein the optical system is adapted to receive the spectroscopy signal at least generally along the zero-axis reference.
12 . The spectrometer of claim 10 wherein the detector is adapted to identify the at least one component of the spectroscopy signal corresponding to the sample via spectral subtraction.
13 . The spectrometer of claim 10 wherein the detector is adapted to identify the at least one component of the spectroscopy signal corresponding to the sample via spectral subtraction of at least one known component.
14 . The spectrometer of claim 10 wherein the detector is adapted to identify the at least one component of the spectroscopy signal corresponding to the sample via spectral subtraction of at least one known component stored in a library.
15 . The spectrometer of claim 14 wherein the library stores spectral interference components of a plurality of known materials.
16 . The spectrometer of claim 14 wherein the plurality of known materials includes a plurality of containers.
17 . The spectrometer of claim 14 wherein the plurality of known materials includes a plurality of plastic containers.
18 . A method of measuring Raman scattering from layers within a sample comprising:
exciting Raman scattering at a nonzero angle relative to a normal angle of incidence relative to the sample; using multiple angles to interrogate the different depths within the sample; collecting Raman spectra at the normal angle of incidence to the surface; and using statistical methods to derive the different layers within the sample.
19 . (canceled)
20 . (canceled)
21 . (canceled)Join the waitlist — get patent alerts
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