Transcript Slide 1

How does diffusion affect radiative efficiency measurements?
Caroline Vaughan and Tim Gfroerer, Davidson College, Davidson, NC
Mark Wanlass, National Renewable Energy Lab, Golden, CO
Motivation
Radiative Recombination
Conduction Band
Conduction Band
ENERGY
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Defect Level
HEAT
Modeling Diffusion
HEAT
LIGHT
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Valence Band
Valence Band
Defect-related recombination occurs when an electron or hole
is trapped in a defect energy level and recombines by releasing
heat. This process takes away from the light produced by LED’s
or the photocurrent generated by solar cells.
Defect-related recombination can lower the efficiency of many semiconductor devices. We
measure the radiative efficiency (the ratio of emitted to incident light) as a function of excitation
laser power to investigate defect-related recombination in GaAs. Images of the emitted light
reveal isolated dark regions where the radiative efficiency is reduced. We found a troubling result
that radiative efficiency seems to be reduced by decreasing the laser excitation area. But our
recombination model is incomplete because it does not account for diffusion or photon recycling.
Our radiative efficiency measurements depend strongly on laser focusing, suggesting that these
factors are important. We seek to model these effects computationally to explain how radiative
efficiency depends on laser excitation area.
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Normalized Photoluminescence Intensity
Defect-related Recombination
Abstract
Focusing Analysis
Experimental Setup
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Radiative Efficiency
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Even though the radiative efficiency
should only depend on the density of
electrons and holes (n), which is
determined by the laser power per area,
we find a large shift in the efficiency curve
when changing the spot size of the laser.
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4.30x10 cm
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7.55x10 cm
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5.21x10 cm
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9.27x10 cm
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7.32x10 cm
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Why might this be?
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400
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Distance From Center (m)
By taking the integral shown above, which accounts for both laser
width and diffusion length, we are able to model the predicted effects
of diffusion1. But there seems to be a discrepancy between theory
and experiment, especially near the laser center. By adding in a
stronger generation rate due to photon recycling, we hope to find a
better fit between the data and what we would theoretically expect.
The recycling generation rate is equal to2:
1. “Direct imaging of anisotropic minority-carrier diffusion in ordered GaInP” N. M. Haegel, T. J. Mills, M. Talmadge, C. Scandrett, C.
L. Frenzen, H. Yoon, C. M. Fetzer, and R. R. King, J. Appl. Phys. 105, 023711 (2009), DOI:10.1063/1.3068196
Photon Recycling
Focused Photoluminescence Horizontal Profiles
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at 7.32x10 cm
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Photoluminescence Intensity
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Diffusion
Raditative Efficiency
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2. “Measurement of 100 μm minority carrier diffusion lengths in p-GaAs by a new photoluminescence method” RJ Nelson, Inst.
Phys. Conf. Ser. No. 45: Chapter 3 (1979)
Power/Area (W/cm )
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Mathematica Diffusion Fit
Experimental Data
0.011 mW
0.5216 mW
2.78 mW
32.4 mW
60.2 mW
High Intensity Laser
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Laser Excitation
Low Intensity Laser
Luminescence
Absorption Event
Recombination Event
Electrons
Holes
Barrier
2m
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1000
1200
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Distance (m)
100 μm
At lower excitations, n is smaller and the diffusion length is longer, so the effective area of
excitation is greater. There are shorter diffusion lengths for high excitation, so the effective
area of excitation is smaller.
Conclusions
Radiative Efficiency at 298K
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Radiative Efficiency
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Efficiency curves are
measurements of the
radiative efficiency
(emitted / absorbed
light) as a function of
laser power per area.
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Unfocused
Defect
NoDefect
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Power/Area (W/cm )
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• When the laser is focused on a defect, we observe a dramatic difference in the way that the
radiative efficiency depends on laser power.
• We observe a puzzling dependence of the radiative efficiency on laser spot size and hypothesize
that it may be due to the diffusion of carriers and an added effect from photon recycling.
•The diffusion could have a large effect for the small laser spot, but would have a negligible effect
on the large laser spot.
•With computer modeling we are working to match our experimental results to a theoretical
hypothesis that would combine the effects of diffusion and photon recycling.
Photon recycling is the re-absorption and possible re-emission of
the photoluminescence emitted. For the focused laser, an emitted
photon is more likely to move outside the small laser excitation
area where n is small and re-emission is unlikely, while on the large
laser spot, an emitted photon is more likely to be re-absorbed
within the laser excitation area where n is large and re-emission is
more probable. Re-absorption within the excitation area creates a
higher net efficiency there, enhancing the photoluminescence.
Acknowledgments
We thank Jeff Carapella for growing the
test structures and the Donors of the
American Chemical Society –
Petroleum Research Fund for supporting
this work.