Solar Spectrum
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Transcript of Solar Spectrum
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Solar Spectrum
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Solar Spectrum
-Black body radiation
Light bulb 3000°KRed->Yellow->White
Surface of Sun 6000°K
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Solar Spectrum
-Black body radiation
Light bulb 3000°KRed->Yellow->White
Surface of Sun 6000°K
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Solar Spectrum
-Black body radiation
Light bulb 3000°KRed->Yellow->White
Surface of Sun 6000°K
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Solar Spectrum
-Atmospheric Absorption and Scattering
Light bulb 3000°KRed->Yellow->White
Surface of Sun 6000°K
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Solar Spectrum
-Atmospheric Absorption and Scattering
Light bulb 3000°KRed->Yellow->White
Surface of Sun 6000°K
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Solar Spectrum
-Atmospheric Absorption and ScatteringAir Mass through which solar radiation
passes
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Solar Spectrum
-Atmospheric Absorption and ScatteringAir Mass through which solar radiation
passes
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30% lost to Rayleigh Scattering λ-4 (blue sky/orange sunset)Scattering by aerosols (Smoke, Dust and Haze S.K. Friedlander)
Absorption: Ozone all below 0.3 µm, CO2, O2, H2O
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10% added to AM1 for clear skies by diffuse componentIncreases with cloud cover
½ lost to clouds is recovered in diffuse radiation
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Direct and Diffuse Radiation
Global Radiation = Direct + Diffuse Radiation
AM1.5 Global AM1.5G irradiance for equator facing 37° tilted surface on earth (app. A1)
Integral over all wavelengths is 970 W/m2 (or 1000 W/m2 for normalized spectrum) is a standard to rate PV Close to maximum power received at the earths surface.
Appendix A1
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Standard Spectrum is compared to Actual Spectrum for a siteSolar Insolation Levels
March
June
September
December
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Cape Town/Melbourne/Chattanooga
Gibraltar/Beirut/Shanghai
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Appendix B
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Need:-Global radiation on a horizontal surface-Horizontal direct and diffuse components of global value-Estimate for tilted plane value
Equations given in Chapter on Sunlight
Peak sun hours reduces a days variation to a fixed number of peak hours for calculations
SSH = Sunshine HoursTotal number of hours above 210 W/m2 for a month
Equations in Chapter 1 to convert SSH to a useful form.
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Estimates of Diffuse Component
Clearness Index KT = diffuse/totalThis is calculaed following the algorithm given in the chapter
Use number of sunny and cloudy days to calculate diffuse and direct insolation Described in the book
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Tilted Surfaces
PV is mounted at a fixed tilt angle
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Sunny versus Cloudy
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Calculation for Optimal Tilt Angle
Given in the Chapter
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P-N Junctions and Commercial Photovoltaic DevicesChapter 2
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Czochralski Process
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Hot Wall CVD
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Plasma CVD
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Market Share
CIS= Copper Indium Gallium Selenidea-Si= Amorphous SiliconRibbon= Multicrystalline Silicon from
Molten BathCdTe= Cadium Telluride/Cadmium SulfideMono = Monocrystalline SilicaonMulti= Muticrystalline Silicon
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Positive ion cores
Negative ion coresDepleted of Free Carriers
http://www.asdn.net/asdn/physics/p-n-junctions.shtml
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Carrier GenerationCarrier RecombinationCarrier DiffusionCarrier Drift in Depletion Region
due to inherent field
On average a minority carrierTravels the diffusion lengthBefore recombiningThis is the diffusion current
Carriers in the depletion regionAre carried by the electric fieldThis is the drift current
In equilibrium drift = diffusionNet current = 0
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I–V characteristics of a p–n junction diode (not to scale—the current in the reverse region is magnified compared to the forward region, resulting in the apparent slope discontinuity at the origin; the actual I–V curve is smooth across the origin).http://en.wikipedia.org/wiki/Diode
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I–V characteristics of a p–n junction diode (not to scale—the current in the reverse region is magnified compared to the forward region, resulting in the apparent slope discontinuity at the origin; the actual I–V curve is smooth across the origin).http://en.wikipedia.org/wiki/Diode
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Electron-hole pair-Generation
-Recombination
Carrier lifetime (1 µs)Carrier diffusion length (100-300 µm)
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N=photon fluxα=abs. coef.
x=surface depthG=generation rate
e-h pairs
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N=photon fluxα=abs. coef.
x=surface depthG=generation rate
e-h pairs
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I0 is dark saturation currentq electron chargeV applied voltage
k Boltzmann ConstantT absolute temperature
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N=photon fluxα=abs. coef.
x=surface depthG=generation rate
e-h pairs
At x = 0 G =αNFunction is G/Gx=0 = exp(-αx)
Electrons absorb the band gap energy
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Diode Equation Photovoltaic Equation
Silicon Solar Cell
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Efficiency of Light Conversion to e-h pair
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Short Circuit Current, V = 0
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Inefficiency of the e-h pair formation and collection process
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Voc drops in T because I0 increases
Open Circuit Voltage
http://pvcdrom.pveducation.org/CELLOPER/TEMP.HTM
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Maximum Power
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Effect of Shunt Resistance on fill factor
http://www.pv.unsw.edu.au/information-for/online-students/online-courses/photovoltaics-devices-applications/syllabus-details
Fill Factor
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Effect of Shunt Resistance on fill factor
http://www.pv.unsw.edu.au/information-for/online-students/online-courses/photovoltaics-devices-applications/syllabus-details
Fill Factor
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Spectral Response
Quantum Efficiency = number of e-h pairs made per photonBand gap determines when this is greater than 0
Need band gap between 1.0 and 1.6 eV to match solar spectrumSi 1.1 eV Cd 1.5 eV
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Issues effecting quantum efficiencyAbsorption spectrum
Band GapSpectral Responsivity = Amps per Watt of Incident Light
Short wavelengths => loss to heatLong wavelengths => weak absorption/finite diffusion length
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Chapter 4 Cell Properties
Lab Efficiency ~ 24%Commercial Efficiency ~ 14%
Lab processes are not commercially viable
C is Cost of Generated ElectricityACC Capital CostO&M is Operating and Maintenance Costt is yearE is energy produced in a yearr is discount rate interest rate/(i.r. + 1)
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C is Cost of Generated ElectricityACC Capital CostO&M is Operating and Maintenance Costt is yearE is energy produced in a yearr is discount rate interest rate/(i.r. + 1)
Increased Efficiency increases E and lowers C.Can also reduce ACC, Installation Costs, Operating CostsTo improve C
For current single crystal or polycrystalline silicon technology Wafer costs account for ½ of the module cost.½ is marketing, shipping, assembly etc.
We can adresss technically only the efficiency E
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Solar Cell Module Efficiency
Optical Losses Due to Reflection
1) Minimize surface contact area(increases series resistance)
2) Antireflection coatings¼ wave platetransparent coating of thicknessd1 and refractive index n1d1 = λ0/(4n1)n1 = sqrt(n0n2)
2) Surface TexturingEncourage light to bounceback into the cell.
1) Absorption in rear cell contact. Desire reflection but atRandom angle for internal reflection
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d1 = λ0/(4n1) n1 = sqrt(n0n2)
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Dobrzanski, Drygala, Surface Texturing in Materials and Manufacturing Engineering, J. Ach. In Mat. And Manuf. Eng. 31 77-82 (2008).
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Reduce recombination at contacts by heavily doping near contacts
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Recombination Losses
Red
Blue
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Recombination Losses
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Recombination Losses
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Bulk & Sheet Resistivity
Sheet Resistivity
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Eglash, Competition improves silicon-based solar cells, Photovoltaics December, 38-41 (2009).
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SunPower San Jose, CA20% eficiency from Czochralski silicon
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Eglash, Competition improves silicon-based solar cells, Photovoltaics December, 38-41 (2009).
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Suntech, Wuxi, Chinamulti crystalline cast silicon
Efficiency 16.5%Cost $1.50 per watt
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Eglash, Competition improves silicon-based solar cells, Photovoltaics December, 38-41 (2009).
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