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opticalspectrometers:start [2020/03/06 09:04] – external edit 127.0.0.1opticalspectrometers:start [2021/08/12 16:45] (current) janet
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 Located in David McIntyre's lab Weniger 118. Located in David McIntyre's lab Weniger 118.
  
-====Scanning Monochromator==== +====Scanning Monochromator (Grating Spectrometer or GS)==== 
-The Scanning Monochromator can make transmission, specular reflection, and diffuse reflection measurements on thin film, single crystal, and powder samples.+The Scanning Monochromator can make transmission, specular reflection, and diffuse reflection measurements on thin film, single crystal, and powder samples. Here is the grating spectrometer manual, written in 2002, parts of which may be obsolete, but the basic structure is OK. 
  
 === Sources === === Sources ===
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 {{:opticalspectrometers:w_spectrum_small.png|:opticalspectrometers:w_spectrum.png}} {{:opticalspectrometers:w_spectrum_small.png|:opticalspectrometers:w_spectrum.png}}
 +
 +A word of caution about the gratings: Reported **problem**, "I found that the monochrometer seems to be having trouble. I tried to reset it to 518 nm and found that thanks to what seems to be a belt problem, it is stuck at 926 nm", David Mc **responded** on (9/12/21), "I (kind of) fixed the spectrometer.  I know what the problem was, but I do not know what caused it.  BUT, YOU should figure out what caused the problem, as it has damaged the instrument already and if it happens again it may further damage the instrument. The indicators on the 2 spectrometers read the wavelength in the range 0-999.  But what they are really doing is indicating the angle of the grating, which is turned with the sets of gears and pulleys.  The indicator that was at 926 nm had arrived at that point not by going from 518 nm up to 926 nm, but rather by going from 518 nm, down to 0 and thorough 0 (to the negative side) and stopping at 926.  Thus the grating was at an angle where no light goes through the spectrometer.  The spectrometer is not designed to go past 0, so the gears and belts locked up.  By removing some belts and applying gentle but firm force, I was able to independently get the 2 spectrometers back into the “positive” region.  With the coupling belt removed, I set one spectrometer to 518 and then adjusted the other by monitoring the spectrometer output.  The output was maximized with the second spectrometer (closer to the lamp) set to 545 nm.  This indicates that the gears and belts slipped quite a bit.  Unfortunately, now we do not know which dial, if either, is correct.  The system needs to be recalibrated.  Moreover, the gears appear to slip during a manual scan and this may cause problems for a computer controlled scan."
  
 ===Sampling Accessories=== ===Sampling Accessories===
 The Scanning Monochromator has an Oriel 70491 integrating sphere to make diffuse reflection measurements. The Scanning Monochromator has an Oriel 70491 integrating sphere to make diffuse reflection measurements.
  
-====Ocean Optics Spectrometer====+====Ocean Optics Spectrometer (OO; also "Fiber Optic Spectrometer")====
 The Ocean Optics Spectrometer can make transmission, specular reflection, and diffuse reflection measurements on thin film, single crystal, and powder samples. Diffuse reflection measurements can only be made on strongly diffusely reflecting materials. The Ocean Optics Spectrometer can make transmission, specular reflection, and diffuse reflection measurements on thin film, single crystal, and powder samples. Diffuse reflection measurements can only be made on strongly diffusely reflecting materials.
  
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     * **To use this and all the other spreadsheets given below you must enable the Solver add-in in the Excel Options Menu**     * **To use this and all the other spreadsheets given below you must enable the Solver add-in in the Excel Options Menu**
       * Under the Excel main menu open "Excel Options", select the "add-ins" menu, "Solve Add-in" and select "Go"       * Under the Excel main menu open "Excel Options", select the "add-ins" menu, "Solve Add-in" and select "Go"
-  * Scout software is being implemented by Aaron Kratzer (2013). [[:ScoutManual|Working user manual]]+  * SCOUT software was worked on by Aaron Kratzer in 2013. Ryan Lance produced templates and instructions in 2017. See Ryan's and Aaron's theses on thesis page, and Ryan's SCOUT intro manual here  [[:ScoutManual|SCOUT instructions and tips]]
   * Update from James Haggerty (05/03/17)   * Update from James Haggerty (05/03/17)
     * Here is an {{:opticalspectrometers:17-0503_optical_data_processing_excel_spreadsheets.zip|optical data processing}} .zip file which contains all the files needed to process both thin film and powder optical data collected on our spectrometers.  Included are the following spreadsheets     * Here is an {{:opticalspectrometers:17-0503_optical_data_processing_excel_spreadsheets.zip|optical data processing}} .zip file which contains all the files needed to process both thin film and powder optical data collected on our spectrometers.  Included are the following spreadsheets
       * **index_calc2015-V009.xlsm**: the latest version of the thin film data processing sheet originally written by Levi Kilcher       * **index_calc2015-V009.xlsm**: the latest version of the thin film data processing sheet originally written by Levi Kilcher
       * **OO_Make_Int_Step_UV-IR-V01.xlsx**: Used to convert both UV-Vis and IR data from the fiber optic spectrometer to integer steps in wavelength.       * **OO_Make_Int_Step_UV-IR-V01.xlsx**: Used to convert both UV-Vis and IR data from the fiber optic spectrometer to integer steps in wavelength.
-      * **Optical_Diff_Gap_Calc - V04.xlsm**: Alternative band gap calculation that does not use the Tauc method.  This meathod uses differentiation of the absorption model as a way to determine the band gap instead of the Tauc method.  This spreadsheet can easily be modified to calculate band gaps for either absolute or relative absorptions.+      * **Optical_Diff_Gap_Calc - V04.xlsm**: Alternative band gap calculation that does not use the Tauc method.  This method uses differentiation of the absorption model as a way to determine the band gap instead of the Tauc method.  This spreadsheet can easily be modified to calculate band gaps for either absolute or relative absorption.
       * **Optical_Plots_Comparisons - V01.xlsx**: Used to incorporate multiple data sets into one plot for trend identification       * **Optical_Plots_Comparisons - V01.xlsx**: Used to incorporate multiple data sets into one plot for trend identification
       * **Optical_Plots_MultiRange-V07.xlsm**: Can be used to make a full spectrum data set from T and R data collected on two different spectrometers or two different regions collected by the same spectrometer.  The plots used setup the data for the calculations of the Swanepole method for calculating absorption.       * **Optical_Plots_MultiRange-V07.xlsm**: Can be used to make a full spectrum data set from T and R data collected on two different spectrometers or two different regions collected by the same spectrometer.  The plots used setup the data for the calculations of the Swanepole method for calculating absorption.
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       * **17-0328_Optical_data_processing-Optical_Plots_V02.pptx**: Step-by-step guide to the optical plots spreadsheets.  This presentation applies to the following spreadsheets:       * **17-0328_Optical_data_processing-Optical_Plots_V02.pptx**: Step-by-step guide to the optical plots spreadsheets.  This presentation applies to the following spreadsheets:
         * Optical_Plots_MultiRange-V07.xlsm, Optical_Plots_SingleRange-V06.xlsm, Optical_Plots_MultiRange_Diffuse-V02.xlsm, Optical_Plots_SingleRange_Diffuse-V02.xlsm, and OO_Make_Int_Step_UV-IR-V01.xlsx         * Optical_Plots_MultiRange-V07.xlsm, Optical_Plots_SingleRange-V06.xlsm, Optical_Plots_MultiRange_Diffuse-V02.xlsm, Optical_Plots_SingleRange_Diffuse-V02.xlsm, and OO_Make_Int_Step_UV-IR-V01.xlsx
 +
 +====Filmetrix Spectrometer (Not used much in 2020)====
  
 ===== Documentation ===== ===== Documentation =====
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 |^Date^Author^Title^Notes| |^Date^Author^Title^Notes|
 |-|-|[[http://www.sspectra.com/sopra.html|Optical constants from Sopra labs]]|Optical constants of many different materials.  Widely quoted site.| |-|-|[[http://www.sspectra.com/sopra.html|Optical constants from Sopra labs]]|Optical constants of many different materials.  Widely quoted site.|
-|Journal of Physical and Chemical Reference Data 9, 561 (1980)|H. H. Li|[[http://www.nist.gov/data/PDFfiles/jpcrd162.pdf|Refractive Index of Silicon and Germanium and Its Wavelength and Temperature Derivatives]]|Exhaustive compilation of ref. ind. of Si, Ge, temp dep etc. Available at NIST reprint site.| +|Journal of Physical and Chemical Reference Data 9, 561 (1980)|H. H. Li|[[http://www.nist.gov/data/PDFfiles/jpcrd162.pdf|Refractive Index of Silicon and Germanium and Its Wavelength and Temperature Derivatives]]|Exhaustive compilation of refractive index of Si, Ge, temp dep etc. Available at NIST reprint site.| 
-|Journal of Physical and Chemical Reference Data 13, 103 (1984)|H. H. Li|[[http://www.nist.gov/data/PDFfiles/jpcrd240.pdf|Refractive Index of ZnS, ZnSe, and ZnTe and its wavelength and temperature derivatives]]|Exhaustive compilation of ref. ind. of ZnCh temp dep etc. Available at NIST reprint site.|+|Journal of Physical and Chemical Reference Data 31, 931 (2002)|R.D. Shannon et al.|[[https://aip.scitation.org/doi/10.1063/1.1497384|Refractive Index and Dispersion of Fluorides and Oxides]]|Exhaustive compilation of refractive index of fits to refractive indices of common fluoride and oxides using Sellmeier formalism.| 
 +|Journal of Physical and Chemical Reference Data 13, 103 (1984)|H. H. Li|[[http://www.nist.gov/data/PDFfiles/jpcrd240.pdf|Refractive Index of ZnS, ZnSe, and ZnTe and its wavelength and temperature derivatives]]|Exhaustive compilation of refractive index of ZnCh temp dep etc. Available at NIST reprint site.|
 |Melles Griot Technical Manual, Materials Properties |Melles Griot|[[http://marketplace.idexop.com/store/SupportDocuments/MaterialProperties.pdf|Materials Properties]]|Good compilation of refractive index, transmission of different kinds of glasses - BK7, suprasil, CaF, crystal quartz, etc.  Also silicon and germanium.| |Melles Griot Technical Manual, Materials Properties |Melles Griot|[[http://marketplace.idexop.com/store/SupportDocuments/MaterialProperties.pdf|Materials Properties]]|Good compilation of refractive index, transmission of different kinds of glasses - BK7, suprasil, CaF, crystal quartz, etc.  Also silicon and germanium.|
 |Melles Griot Technical Manual, Optical Coatings |Melles Griot|[[http://marketplace.idexop.com/store/SupportDocuments/1-Optical%20Coating%20and%20Materials.pdf|Optical Coatings]]|Good discussion of coatings and materials, reflection, angles of incidence, phase changes, fringes etc.| |Melles Griot Technical Manual, Optical Coatings |Melles Griot|[[http://marketplace.idexop.com/store/SupportDocuments/1-Optical%20Coating%20and%20Materials.pdf|Optical Coatings]]|Good discussion of coatings and materials, reflection, angles of incidence, phase changes, fringes etc.|

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