1. Solar: Why and How? Opportunities and Challenges
ELCT 101 Solar Module Kickoff

2. Problem Statement There is too much dependence on foreign oil!!
Energy Production
Increased production
More sustainable production
Energy Usage
More efficient systems-
More responsible usage-clean?

3. Global warming, environmental fallout 10’s years infrastructure
The Green Economy
>107 years
Carbon emissions
Fossil Fuels
Ethanol
Global warming, environmental fallout
Sun
Water cycle
Water Vapor
emissions
Hydrogen Production
Photovoltaics/wind
10’s years infrastructure
Production -days
CLEAN, RENEWABLE ENERGY!!
Fuel storage transportation, power distribution

4. SOLAR ENERGY PRODUCTION

5. Photoelectrochemical?
The Dream
Shine light on it and you get lots of clean fuel/power
How much?
How quickly?
What kind?
Payback time?
Other?
Photoelectrochemical?
Hydrogen
Photovoltaic
Electricity

6. Solar Energy Production Light Absorption in Semiconductors
Energy re-emitted
Light/heat or both Ec
Elight
Bandgap Eg
If Elight >Bandgap
ABSORPTION! Ev h+ e-
Electric field is simplest way to separate charge
Pn junction is traditional way
Efficient absorber/emitter of light-Direct Gap
Bandgap determines color of light
Absorbed light→ electricity vs. heat/light

7. Solar Energy Production Charge Separation in Semiconductors!
Electric field is simplest way to separate charge
Pn junction is traditional way
Recombine
Electrical energy released!
Key is charge separation in electric field
How to produce this field?

8. Producing an Electric Field-Junctions
Charge separation at interface
liquid
Solid e-
p-type e-
n-type
Redox energies in liquid e.g. H2O h+ h+
Solid-liquid junction
Single solid type
Liquid fills in all gaps
continuous interface
Solid-solid junction
Same material
different impurity levels
Interface of two electrically different materials
Potential Hill-like water in gravity
Perfection/abruptness of interface desirable

9. Solid/Solid vs. Solid/Liquid Junction
TiO2 -Barbe et al., Cahen et. al
Challenges include
Contacting each powder together
Chemical stability of surface-
Solid-solid more robust- difficult to produce
8 year energy payback time (single crystal 12-30%)
Liquid can fill in gaps easily-can use powders
Greater engineering challenge to achieve 10-20%

10. Solar Hydrogen Production
Elight =hv
H+/H2
H2O/O2 EF Ec Ev
Non-corrosive counter electrode
Semiconductor
Water redox potentials h+
O2 evolved
H2 evolved h+
Discovered with TiO2 electrodes in 1972*
Now looking at making methanol from CO2 in water.
*Fujishima, Honda, Nature, 1972, 238, 37

11. Dye-Sensitized Solar Cells-Gratzel Cells
Elight
dye e-
mediator S
solid
semiconductor
liquid
Dye can change color sensitivity-photo film
Everything is regenerated-can start again
>10% efficient like a-Si solar cells

12. EFFICIENT ENERGY USAGE

13. Energy Usage EFFICIENCY! But coupled with payback time?
Solid-state GaN single crystal LED lighting efficiency comparable to compact fluorescent (CFL) ~9-15%
Much poorer payback time!
SiC electrical power conversion devices gaining traction-TranSiC, Cree, Toyota
Small devices-reasonable payback time
Energy economies of scale?
SiC suitable for harsh environments e.g. engine
Emissions monitoring/controls

14. LIGHTING

15. Compact Fluorescent LampsUV
Blue
Green
Red
UV emitted from Hg sources
UV downconverted to visible using phosphors
Well balanced white light required
Efficiency of CFL limited by phosphors
254nm vs. 365nm→ 4.9eV vs. 3.4 eV (GaN)
improve efficiency by ~20%

16. GaN-powder Based Phosphors
Pump Elight_in UV
Elight_out
RED
GaN:Eu
Shi, Chandrashekhar et. al, J. Cryst. Gr. (2007)
Elight_in Ec
Fast energytransfer to impurity-lost as heat
Bandgap Eg
Impurity
Elight_out Ev e- h+
Pump with above bandgap light-UV
Emits light at lower energy
red (Eu)/green (Er)/Blue (pure)=WHITE!

17. Novel “Solid-State” GaN Lighting
Electroluminescent lamp with DC
Electroluminescent lamp with AC
Steckl et. al, IEEE STQE (2002)
Cheap electrophoretically deposited electrodes/phosphors
Solid/liquid OR solid/solid junction
DC or AC voltage electroluminescent lamps
Geometries similar to single crystal-performance?

18. EMISSIONS

19. Gas Sensing and Efficiency/Emissions
Percent by volume (Building)
Percent by Volume (automotive)
Short Term Occupational Exposure Limit
(ppm)
Long Term Occupational Exposure Limit (ppm)
Enforceable limit
NO2 *
<1ppm
1-10 ppm 20 1 10
CO2
<1%
20%
H2O*
<5%
10% O2
21% 3%
CO*
2000 ppm
1200 50
<30
Higher O2 intake→ Greater Engine Efficiency
Higher O2 intake → Higher NO2 emissions
NO2 1ppm is considered harmful-enforceable?
Europe deploys Urea for NO2 removal-controls

20. Graphene/SiC for Sensing Polar Molecules
Graphene resistance changes in response to molecule on surface
Electrical Probe
Capacitances change in response to molecule on surface
Graphene
Single molecule sensitivity to NO2 observed in small samples of graphene/SiO2
Large area graphene films produced on SiC
Other molecules can be sensed also H2O, CO etc.

21. Graphene/SiC for Sensing NO2
Chandrashekhar et. al, IEEE Sensors (2007)
Sensed<1ppm NO2 using capacitive means
Suitable for environmental/emissions controls
Challenges-cross-sensitivity, durability?