YU-CHUN YEH The University of South Carolina
50
YU-CHUN YEH The University of South Carolina 1
Transcript of YU-CHUN YEH The University of South Carolina
Dye-Sensitized Solar Cell1
Outline
Grätzel
1991
353, 737-740. 5
3D surface structure of TiO2 film in range 25
μm2. 10
3. Principles
LUMO level.
moved to LUMO level become
injected into nanoparticle semiconductor.
16
extracted to a load where the work done is
delivered as an electrical energy.
17
TiO2 photoelectrode and the carbon coated
counter electrode.
are regenerated by receiving electrons from
the I- ion redox mediator that get oxidized to I3 -.
20
electron with that from the external load and
reduced back to I- ion.
22
film
31
with dye molecules (from
34
cell
35
the photovoltage and
37
High performance-price ratio
(Photovoltaics) Technologies.
Newcastle (Australia)– the first commercial
DSSC module
cells leaves (AISIN SEIKI CO.,LTD)
45
developed by Dyesol (http://www.dyesol.com)
(http://www.g24i.com).
47
414,15,338-344 (2001)
Electron Transfer and Nanotechnology:A Natural Dye–
Sensitized Nanocrystalline Energy Converter” Journal of
Chemical Education, Vol. 75 ,No. 6 ,752-756, June 1998
3. -
376
sensitized solar cell (DSSC)” 10/15/2010
6. DIY
7. Yat Li, University of California, Santa Cruz, Making a Solar
Cell with TiO2 Nanoparticles 48
7. Khalil Ebrahim Jasim, Dye Sensitized Solar Cells - Working
Principles, Challenges and Opportunities
8. Nur Munirah Abdullah, Anika Zafiah M. Rus, M.F.L Abdullah,
Influence of Additive on The Performance of Energy Conversion
Solar Cell
9. William A. Vallejo L., Cesar A. Quiñones S. and Johann A.
Hernandez S., The Chemistry and Physics of Dye-Sensitized Solar
Cells
John T., Investigating dye-sensitised solar cells
11. Neal M. Abrams, Using Nature to Make a Photovoltaic Cell
12. IRENA WORKING PAPER, RENEWABLE ENERGY
TECHNOLOGIES: COST ANALYSIS SERIES
Outline
Grätzel
1991
353, 737-740. 5
3D surface structure of TiO2 film in range 25
μm2. 10
3. Principles
LUMO level.
moved to LUMO level become
injected into nanoparticle semiconductor.
16
extracted to a load where the work done is
delivered as an electrical energy.
17
TiO2 photoelectrode and the carbon coated
counter electrode.
are regenerated by receiving electrons from
the I- ion redox mediator that get oxidized to I3 -.
20
electron with that from the external load and
reduced back to I- ion.
22
film
31
with dye molecules (from
34
cell
35
the photovoltage and
37
High performance-price ratio
(Photovoltaics) Technologies.
Newcastle (Australia)– the first commercial
DSSC module
cells leaves (AISIN SEIKI CO.,LTD)
45
developed by Dyesol (http://www.dyesol.com)
(http://www.g24i.com).
47
414,15,338-344 (2001)
Electron Transfer and Nanotechnology:A Natural Dye–
Sensitized Nanocrystalline Energy Converter” Journal of
Chemical Education, Vol. 75 ,No. 6 ,752-756, June 1998
3. -
376
sensitized solar cell (DSSC)” 10/15/2010
6. DIY
7. Yat Li, University of California, Santa Cruz, Making a Solar
Cell with TiO2 Nanoparticles 48
7. Khalil Ebrahim Jasim, Dye Sensitized Solar Cells - Working
Principles, Challenges and Opportunities
8. Nur Munirah Abdullah, Anika Zafiah M. Rus, M.F.L Abdullah,
Influence of Additive on The Performance of Energy Conversion
Solar Cell
9. William A. Vallejo L., Cesar A. Quiñones S. and Johann A.
Hernandez S., The Chemistry and Physics of Dye-Sensitized Solar
Cells
John T., Investigating dye-sensitised solar cells
11. Neal M. Abrams, Using Nature to Make a Photovoltaic Cell
12. IRENA WORKING PAPER, RENEWABLE ENERGY
TECHNOLOGIES: COST ANALYSIS SERIES
