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Photoconductors

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Upper cutoff: Bandgap of Semiconductor. Lower cutoff: High absorption ... Dominant in Low Bandgap structures. Low temperature operation. Temperature Noise ... – PowerPoint PPT presentation

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Title: Photoconductors


1
Photoconductors
  • Rajeev V Shenoi
  • Centre for High Technology Materials
  • University of New Mexico

2
Photodetectors
  • Convert Optical energy to electrical energy.
  • Parameter changes by light detection.

3
Classification
  • Extrinsic
  • Lower energy than bandgap
  • Interband transitions
  • Trap states
  • Intrinsic
  • energy equal to bandgap
  • Band to band transitions
  • Photvoltaic
  • Potential barrier to separate generated EHP
  • Asymmetric characteristics
  • Photoconductive
  • Photogeneration of carriers.
  • Change in conductivity.

4
Quantum Efficiency
  • Number of Independent electons per photon
  • Excludes gain mechanism
  • Depends on absorption
  • Upper and lower cutoff exhibited

5
Responsivity
  • Current produced per unit radiation incident
  • Linear function of wavelength
  • Upper cutoff Bandgap of Semiconductor
  • Lower cutoff High absorption

6
Noise Sources
Johnson Noise Shot Noise Generation-Recombinatio
n Noise Temperature Fluctuation Barkheusen
Noise 1/f Noise
7
Johnson Noise
  • Thermal Motion of Carriers
  • Contributes to dark current
  • Gaussian Statistics
  • White Spectral Density
  • Dominant source at High Frequency
  • Varies as square root of Detector Area

8
Shot Noise
  • Stream of electrons generated at random times
  • White spectral density
  • Gaussian Statistics
  • Correlated with Signal Current
  • Varies as square root of Detector Area

9
Shot Noise
  • Fluctuations in Generation and Recombination
    Process.
  • Dominant in Low Bandgap structures
  • Low temperature operation

Temperature Noise
  • Changes in the temperature of the material
  • Important in Thermal Detectors.

10
Flicker Noise (1/f noise)
  • Due to ohmic contacts at electrodes
  • Surface traps
  • Dominant at low frequencies

Barkheusen Noise (Popcorn Noise
  • Impact ionization of neutral impurities.
  • Due to defect in lattices and contacts.
  • Observed as a spike in the output

Total Noise
11
Signal To Noise Ratio
Noise Equivalent Power
  • Signal power when SNR1
  • Measure of Sensitivity of Detector
  • Lower NEP is better.
  • Depends on Detector Area and Bandwidth

12
Detectivity
  • Intrinsic Figure of Merit
  • Normalized for Detector Area and Bandwidth
  • Higher Detectivity is better
  • Linear relationship with wavelength

Noise Equivalent Irradiance
  • Input flux density when SNR1

13
Noise Equivalent Temperature Difference
  • Measure of Sensitivity for FPA
  • Temperature Difference equivalent to SNR1
  • Smaller NETD is better
  • Depends on and
  • No information on spatial resolution

rms Noise
Signal measured
14
Minimum Resolvable Temperature Difference
  • Combination of Thermal and Spatial Sensitivity
  • Low Frequencies Thermal Sensitivity
  • High Frequencies- Spatial Sensitivity
  • Thermal Sensitivity as function of Spatial
    Frequency
  • Higher MRTD is better.

15
What is the maximum Responsivity possible at 8?m?
Assume
16
Thank You
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