Optics: measuring and testing – By dispersed light spectroscopy – With raman type light scattering
Reexamination Certificate
2000-09-08
2001-08-28
Evans, F L (Department: 2877)
Optics: measuring and testing
By dispersed light spectroscopy
With raman type light scattering
Reexamination Certificate
active
06281971
ABSTRACT:
FIELD OF THE INVENTION
The present invention pertains generally to the field of spectroscopy. More particularly, the present invention pertains to an apparatus and method for adjusting spectral measurements to achieve a standard Raman spectrum. The present invention is particularly, but not exclusively, novel and useful for determining a standard Raman spectrum by adjusting spectral measurements affected by one or more frequency shifts.
BACKGROUND OF THE INVENTION
Spectroscopy is a general term for the process of measuring energy or intensity as a function of wavelength in a beam of light or radiation. Many conventional spectroscopes, and components comprising a spectroscope system, also referred to as an instrument, may include basic features and components such as a slit and a collimator for producing a parallel beam of radiation, one or more prisms or gratings for dispersing radiation through differing angles of deviation based on wavelength, and apparatus for viewing dispersed radiation. Spectroscopy uses absorption, emission, or scattering of electromagnetic radiation by atoms, molecules or ions to qualitatively and quantitatively study physical properties and processes of matter.
Light or radiation directed at a target, or sample of physical matter, during operation of a spectroscope system may be referred to as incident radiation. Redirection of incident radiation following contact with a sample of physical matter (“sample”) commonly is referred to as scattering of radiation. To the extent that atoms or molecules in a sample absorb all or a portion of incident radiation, rather than reflect incident radiation, a sample may become excited, and the energy level of the sample may be increased to a higher energy level. Electromagnetic radiation, including incident radiation, that passes through a sample, may produce a small portion of light that is scattered in a variety of directions. Light that is scattered but continues to have the same wavelength as the incident radiation will also have the same energy, a condition often referred to as Rayleigh or elastically scattered light. Incident radiation that is scattered during a change of vibrational state in molecules may be scattered with a different energy, and such scattered light may be called Raman scattered light. Such phenomena have been used in conjunction with spectroscopy to qualitatively and quantitatively study physical properties and processes, including identification of chemical properties, compositions, and structures of a sample.
A wave associated with electromagnetic radiation may be described by wavelength, the physical length of one complete oscillation, and by frequency of the wave, the number of oscillations per second that pass a point. If incident radiation is directed at a sample, the wavelength of the incident radiation may remain substantially unchanged in scattered radiation. Alternatively, if incident radiation is directed at a sample, the wavelength in the scattered radiation may acquire one or more different wavelengths than the incident wavelength. The energy differential between the incident radiation and the scattered radiation may be referred to as a Raman shift. Spectroscopic measurement of Raman scattered light seeks in part to measure the resulting wavelength of such scattered light.
Raman scattered light may occur at wavelengths shifted from the incident light by quanta of molecular vibrations. The phenomenon of Raman scattered light, therefore, is useful in spectroscopy applications for studying qualities and quantities of physical properties and processes, including identification of chemical properties, compositions, and structure in a sample. Currently, Raman shift spectroscopic analytical techniques are used for qualitative and quantitative studies of samples. If incident radiation is used to scatter light from a sample, and scattered radiation data is measured, the scattered radiation may provide one or more frequencies associated with the sample, as well as the intensities of those shifted frequencies. The frequencies may be used to identify the chemical composition of a sample. If, for example, intensities are plotted on a Y-axis, and frequency or frequencies are plotted on an X-axis, the frequency or frequencies may be expressed as a wave number, the reciprocal of the wavelength expressed in centimeters. The X-axis, showing frequency or frequencies, may be converted to a Raman shift in wave numbers, the measure of the difference between the observed wave number position of spectral bands, and the wave number of radiation appearing in the incident radiation.
While these principles and phenomena are known, until recently efforts to apply the principles and phenomena to qualitative and quantitative analyses of samples have not always resulted in uniform, predictable results, or in acceptable levels of precision and accuracy of Raman spectra. Because of instrumentation variabilities, inherent weakness of a Raman scattered signal, fluorescence, and other limitations associated with spectroscopy instruments, the goal of producing a standard Raman spectrum for use in sample analyses was, until recently, a challenge not achieved by apparatus and methods known in the art.
At least one problem that had to be overcome was the fact that spectroscopic measurements of Raman scattered light seeking to measure wavelength or intensities, or both, of scattered light, could be affected by the instrument, or spectroscopic system, itself. A number of components of an instrument may contribute individually and collectively to undesirable instrumentation variabilities that affect spectral data measured by the instrument. Raman scattered radiation from a sample may be observed, measured, and directed through an instrument by optics of a spectrometer, may be coded by a device such as an interferometer, and may be directed to one or more detectors to record Raman spectra. Any one, or all, of such components of a conventional spectrometer system induced or contributed to instrumentation variabilities that reduced or adversely affected the precision and accuracy of measurements of Raman scattered light.
In addition to fluorescence, spectral measurements of a source of incident radiation such as a laser, including semiconductor or diode lasers, will evidence other varying baseline components, artifactual or real, that preferably could be eliminated, suppressed, or compensated for to provide an accurate Raman spectrum for analytical purposes. In instrumentation designs preferred by users of Raman technology, semiconductor diode lasers would be the choice of incident radiation due to small and compact sizing, low heat dissipation, and high energy conversion efficiency. Use of semiconductor or diode lasers, while useful because of a number of important characteristics, also engender unique problems that, if solved, would advance Raman technology. However, at least one other problem associated with semiconductor diode lasers is the tendency for the output to change from one frequency to another during operation, commonly referred to as frequency drift. Frequency drift is generally related to temperature variations that may cause either slow frequency drifts or drastic frequency changes. Semiconductor diode lasers also are susceptible to mode hops when the laser switches output from one frequency to a new preferred frequency.
Some of the problems associated with frequency shifts were discussed as early as 1991 in
Semiconductor Diode Lasers Volume I
, edited by William Streifer and Michael Ettenberg, IEEE Press (1991), a work incorporated by reference into this document. In general, frequency shifts, or mode hops, are inherent in laser light, and can be eliminated only by redesigning the laser at excessive cost. Solutions for overcoming the effects of frequency shifts have included redesign of the internal cavity of lasers, designing what is known as an external cavity for lasers, and tuning a range of modes into a single mode. All of those solutions are achieved at considerable expense, and generally shorten th
Allen Fritz Schreyer
Zhao Jun
Evans F L
New Chromex, Inc.
Regan Ray R.
LandOfFree
Method for adjusting spectral measurements to produce a... does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with Method for adjusting spectral measurements to produce a..., we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Method for adjusting spectral measurements to produce a... will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-2527620