Apparatus and method for real time measurement of substrate temperatures for use in semiconductor growth and wafer processing

US 7,837,383 B2
Filed: 04/17/2008
Issued: 11/23/2010
Est. Priority Date: 10/09/2003
Status: Active Grant

First Claim

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1. A method for determining the temperature of a semiconductor material by spectral analysis in an environment where there are light signals from wanted and unwanted sources, said method comprising the steps of:

providing a semiconductor material;

interacting light signals with the semiconductor material to produce diffusely scattered light;

collecting light in a spectrometer to produce spectra data by resolving light signals into discrete wavelength components of particular light intensity, the light containing both diffusely scattered light from the semiconductor material along with a component of unwanted light signals;

identifying an absorption edge region in the spectra data;

deriving a band edge wavelength value as a function of the identified absorption edge region;

inferring a temperature of the semiconductor material based on the derived band edge wavelength value;

and subtracting the unwanted light component from the spectra data before said step of deriving a band edge wavelength to create preprocessed spectra, whereby the temperature of a semiconductor material can be determined without modulating the wanted light signal prior to said collecting step;

wherein said step of subtracting the unwanted light component includes determining a point of interest wavelength within the spectra data using a derivative calculation.

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Abstract

The invention is an optical method and apparatus for measuring the temperature of semiconductor substrates in real-time, during thin film growth and wafer processing. Utilizing the nearly linear dependence of the interband optical absorption edge on temperature, the present method and apparatus result in highly accurate measurement of the absorption edge in diffuse reflectance and transmission geometry, in real time, with sufficient accuracy and sensitivity to enable closed loop temperature control of wafers during film growth and processing. The apparatus operates across a wide range of temperatures covering all of the required range for common semiconductor substrates.

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7 Claims

1. A method for determining the temperature of a semiconductor material by spectral analysis in an environment where there are light signals from wanted and unwanted sources, said method comprising the steps of:
- providing a semiconductor material;
  
  interacting light signals with the semiconductor material to produce diffusely scattered light;
  
  collecting light in a spectrometer to produce spectra data by resolving light signals into discrete wavelength components of particular light intensity, the light containing both diffusely scattered light from the semiconductor material along with a component of unwanted light signals;
  
  identifying an absorption edge region in the spectra data;
  
  deriving a band edge wavelength value as a function of the identified absorption edge region;
  
  inferring a temperature of the semiconductor material based on the derived band edge wavelength value;
  
  and subtracting the unwanted light component from the spectra data before said step of deriving a band edge wavelength to create preprocessed spectra, whereby the temperature of a semiconductor material can be determined without modulating the wanted light signal prior to said collecting step;
  
  wherein said step of subtracting the unwanted light component includes determining a point of interest wavelength within the spectra data using a derivative calculation.
- View Dependent Claims (2, 3)
- - 2. The method of claim 1 wherein said step of determining the point of interest wavelength includes the steps of:
    - a) calculating a 1st derivative of the spectra data;
      
      b) identifying a peak feature of the 1st derivative within the absorption edge region;
      
      c) making a linear fit to the absorption edge region at the wavelength position of the 1st derivative peak;
      
      d) extrapolating the linear fit to determine a wavelength position for subtraction of the unwanted light component.
  - 3. The method of claim 1 wherein said step of determining a point of interest wavelength includes the steps of:
    - a) calculating a 2nd derivative of the spectra data;
      
      b) identifying a peak feature of the 2nd derivative within the absorption edge region;
      
      c) using the spectra intensity value at the 2nd derivative peak, or the intensity value just prior to the 2nd derivative peak, as the unwanted light component to subtract.

4. A method for determining the temperature of a semiconductor material by spectral analysis in an environment where there are light signals from wanted and unwanted sources, said method comprising the steps of:
- providing a semiconductor material;
  
  interacting light signals with the semiconductor material to produce diffusely scattered light;
  
  collecting light in a spectrometer to produce spectra data by resolving light signals into discrete wavelength components of particular light intensity, the light containing both diffusely scattered light from the semiconductor material along with a component of unwanted light signals;
  
  identifying an absorption edge region in the spectra data;
  
  deriving a band edge wavelength value as a function of the identified absorption edge region;
  
  inferring a temperature of the semiconductor material based on the derived band edge wavelength value;
  
  and subtracting the unwanted light component from the spectra data before said step of deriving a band edge wavelength to create preprocessed spectra, whereby the temperature of a semiconductor material can be determined without modulating the wanted light signal prior to said collecting step;
  
  wherein said step of deriving the band edge wavelength value includes the steps of;
  
  a) calculating a 1st derivative of the preprocessed spectra;
  
  b) identifying a peak feature of the 1st derivative within the absorption edge region;
  
  c) making a linear fit to the absorption edge region at the wavelength position of the 1st derivative peak;
  
  d) extrapolating the linear fit to determine the band edge wavelength.

5. A method for determining the temperature of a semiconductor material by spectral analysis in an environment where there are light signals from wanted and unwanted sources, said method comprising the steps of:
- providing a semiconductor material;
  
  interacting light signals with the semiconductor material to produce diffusely scattered light;
  
  collecting light in a spectrometer to produce spectra data by resolving light signals into discrete wavelength components of particular light intensity, the light containing both diffusely scattered light from the semiconductor material along with a component of unwanted light signals;
  
  identifying an absorption edge region in the spectra data;
  
  deriving a band edge wavelength value as a function of the identified absorption edge region;
  
  inferring a temperature of the semiconductor material based on the derived band edge wavelength value;
  
  and subtracting the unwanted light component from the spectra data before said step of deriving a band edge wavelength to create preprocessed spectra, whereby the temperature of a semiconductor material can be determined without modulating the wanted light signal prior to said collecting step;
  
  wherein said step of deriving a band edge wavelength value includes;
  
  a) calculating a 2nd derivative of the preprocessed spectra;
  
  b) identifying a peak feature of the 2nd derivative within the absorption edge region;
  
  c) using the 2nd derivative peak wavelength position as the band edge wavelength.

6. A method for determining the temperature of a semiconductor material by spectral analysis in an environment where there are light signals from wanted and unwanted sources, said method comprising the steps of:
- providing a semiconductor material;
  
  interacting light signals with the semiconductor material to produce diffusely scattered light;
  
  collecting light in a spectrometer to produce spectra data by resolving light signals into discrete wavelength components of particular light intensity, the light containing both diffusely scattered light from the semiconductor material along with a component of unwanted light signals;
  
  identifying an absorption edge region in the spectra data;
  
  deriving a band edge wavelength value as a function of the identified absorption edge region;
  
  inferring a temperature of the semiconductor material based on the derived band edge wavelength value;
  
  and subtracting the unwanted light component from the spectra data before said step of deriving a band edge wavelength to create preprocessed spectra, whereby the temperature of a semiconductor material can be determined without modulating the wanted light signal prior to said collecting step;
  
  further including the step of constructing a calibration function of band edge wavelength versus inferred semiconductor material temperature, and wherein said step of inferring a temperature of the semiconductor material includes correlating the band edge wavelength value to a temperature using a calibration function.
- View Dependent Claims (7)
- - 7. The method of claim 6 wherein said step of constructing a calibration function includes collecting spectra data from semiconductor materials at predetermined temperatures.

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Current Assignee
k-Space Associates, Inc.
Original Assignee
k-Space Associates, Inc.
Inventors
Williams, Jason, Clarke, Roy, Barlett, Darryl, Perry, Douglas, Taylor, Charles A. II
Primary Examiner(s)
VERBITSKY, GAIL KAPLAN

Application Number

US12/104,938
Publication Number

US 20090177432A1
Time in Patent Office

950 Days
Field of Search

374/120, 374/121, 374/124, 374/129, 374/130, 374/131, 374/161, 374/45, 374/100, 374/141, 374/170, 702/134, 438/795, 422/82.12, 356/302, 356/303, 356/309, 356/319, 356/320, 356/326, 356/336, 356/342, 356/300, 356/301, 356/307, 356/306, 356/451, 356/456, 356/419, 356/43, 385/5, 359/599, 359/707, 324/765
US Class Current

374/121
CPC Class Codes

C23C 16/46   characterised by the method...

C23C 16/52   Controlling or regulating t...

G01J 3/024   using means for illuminatin...

G01J 3/0286   Constructional arrangements...

G01J 3/0291   Housings; Spectrometer acce...

G01J 3/10   Arrangements of light sourc...

G01J 5/0003   for sensing the radiant hea...

G01J 5/0007   of wafers or semiconductor ...

G01J 5/0821   Optical fibres

G01J 5/60   using determination of colo...

Apparatus and method for real time measurement of substrate temperatures for use in semiconductor growth and wafer processing

First Claim

1 Assignment

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Abstract

Citations

7 Claims

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Apparatus and method for real time measurement of substrate temperatures for use in semiconductor growth and wafer processing

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

Citations

7 Claims

Specification

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Solutions

Use Cases

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