Photovoltaic Cells. Nanocrystalline Dye Sensitized Solar Cell.
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Transcript of Photovoltaic Cells. Nanocrystalline Dye Sensitized Solar Cell.
Photovoltaic Cells
Nanocrystalline Dye Sensitized Solar Cell
Outline
• Cell Schematic
• Useful Physics
• Construction Procedure• Preparation and
deposition of TiO2 (10-50 nm diameter)
• Preparation of dye and staining semi-conducter
• Carbon Coating counter-electrode
• Assemblage
• Electric Output
• Data Analysis
• Conclusion
Schematic of the Graetzel Cell
Theory and Physics
•The adsorbed dye molecule absorbs a photon forming an excited state. [dye*]
•The excited state of the dye can be thought of as an electron-hole pair (exciton).
•The excited dye transfers an electron to the semiconducting TiO2 (electron injection). This separates the electron-hole pair leaving the hole on the dye. [dye*+]
•The hole is filled by an electron from an iodide ion. [2dye*+ + 3I- 2dye + I3-]
•Electrons are collected from the TiO2 at the cathode.
•Anode is covered with carbon catalyst and injects electrons into the cell regenerating the iodide.
•Redox mediator is iodide/triiodide (I-/I3-)
•The dashed line shows that some electrons are transferred from the TiO2 to the triiodide and generate iodide. This reaction is an internal short circuit that decreases the efficiency of the cell.
Key Step – Charge Separation
Charge must be rapidly separated to prevent back reaction.
Dye sensitized solar cell, the excited dye transfers an electron to the TiO2 and a hole to the electrolyte.
In the PN junction in Si solar cell has a built-in electric field that tears apart the electron-hole pair formed when a photon is absorbed in the junction.
Chemical Note
Triiodide (I3-) is the brown ionic species that
forms when elemental iodine (I2) is dissolved in water containing iodide (I-).
32 I II
Construction Procedure
• TiO2 Suspension Preparation
• TiO2 Film Deposition
• Anthrocyanin Dye Preparation and TiO2 Staining
• Counter Electrode Carbon Coating
• Solar Cell Assembly
Preparing the TiO2 Suspension
• Begin with 6g colloidal Degussa P25 TiO2
• Incrementaly add 1mL nitric or acetic acid solution (pH 3-4) nine times, while grinding in mortar and pestle
• Add the 1mL addition of dilute acid solution only after previous mixing creates a uniform, lump-free paste
• Process takes about 30min and should be done in ventilated hood
• Let equilibrate at room temperature for 15 minutes
Deposition of the TiO2 Film
• Align two conductive glass plates, placing one upside down while the one to be coated is right side up
• Tape 1 mm wide strip along edges of both plates
• Tape 4-5 mm strip along top of plate to be coated
• Uniformly apply TiO2 suspension to edge of plate
• 5 microliters per square centimeter
• Distribute TiO2 over plate surface with stirring rod
• Dry covered plate for 1 minute in covered petri dish
Deposition of the TiO2 Film (cont.)
• Anneal TiO2 film on conductive glass
• Tube furnace at 450 oC
• 30 minutes
• Allow conductive glass to cool to room temperature; will take overnight
• Store plate for later use
Preparation photos
Safety first!
Mixing the TiO2
Working under the hood
Applying the TiO2
Examples: TiO2 Plate
Good Coating:
Mostly even distribution
Bad Coating:
Patchy and irregular
The thicker the coating, the better the plate will perform
Preparing the Anthrocyanin Dye
• Natural dye obtained from green chlorophyll
• Red anthocyanin dye
• Crush 5-6 blackberries, raspberries, etc. in 2 mL deionized H2O and filter (can use paper towel and squeeze filter)
Dye Preparation
Dye comes from black berries
Crushing the berries
Staining the TiO2 Film
• Soak TiO2 plate for 10 minutes in anthocyanin dye
• Insure no white TiO2 can be seen on either side of glass, if it is, soak in dye for five more min
• Wash film in H2O then ethanol or isopropanol
• Wipe away any residue with a kimwipe
• Dry and store in acidified (pH 3-4) deionized H2O in closed dark-colored bottle if not used immediately
Filter and Staining the TiO2
Petri dish
TiO2 glass
Carbon Coating the Counter Electrode
• Apply light carbon film to second SnO2 coated glass plate on conductive side
• Soft pencil lead, graphite rod, or exposure to candle flame
• Can be performed while TiO2 electrode is being stained
SnO2 pre-coated glass
Assembling the Solar Cell
• Remove, rinse, and dry TiO2 plate from storage or staining plate
• Place TiO2 electrode face up on flat surface
• Position carbon-coated counter electrode on top of TiO2 electrode
• Conductive side of counter electrode should face TiO2 film
• Offset plates so all TiO2 is covered by carbon-coated counter electrode
• Uncoated 4-5 mm strip of each plate left exposed
Assembling the Solar Cell
• Place two binder clips on longer edges to hold plates together (DO NOT clip too tight)
• Place 2-3 drops of iodide electrolyte solution at one edge of plates
• Alternately open and close each side of solar cell to draw electrolyte solution in and wet TiO2 film
• Ensure all of stained area is contacted by electrolyte
• Remove excess electrolyte from exposed areas
• Fasten alligator clips to exposed sides of solar cell
Measuring the Electrical Output
• To measure solar cell under sunlight, the cell should be protected from UV exposure with a polycarbonate cover
• Attach the black (-) wire to the TiO2 coated glass
• Attach the red (+) wire to the counter electrode
• Measure open circuit voltage and short circuit current with the multimeter.
• For indoor measurements, can use halogen lamp
• Make sure light enters from the TiO2 side
Multimeterlight
solar cell
Testing Circuit
PhotoCell
Voltmeter
Ammeter
Potentiometer
Measuring the Electrical Output
• Measure current-voltage using a 500 ohm potentiometer
• The center tap and one lead of the potentiometer are both connected to the positive side of the current
• Connect one multi-meter across the solar cell, and one lead of another meter to the negative side and the other lead to the load
Voltage Current
0.242 0
0.22 0.003
0.21 0.004
0.17 0.006
0.13 0.008
0.1 0.01
0.08 0.012
0.041 0.016
Data Analysis
• Plot point-by-point current/voltage data pairs at incremental resistance values, decrease increments once line begins to curve
• Plot open circuit voltage and short circuit current values
• Divide each output current by the measured dimensions of stained area to obtain mA/cm2
• Determine power output and conversion efficiency values
VI characteristic
0
0.002
0.0040.006
0.008
0.01
0.0120.014
0.016
0.018
0 0.1 0.2 0.3
Voltage
Cur
rent Series1
Excel generated plot of dataOpen circuit voltage 0.242mV
Data Analysis Continued
• Max Power– 1.025µW @ 0.14mV
• Max Power per unit area– Photocell area = 34.2 cm2
– 0.003µW/cm2
Power curve
0
0.0002
0.0004
0.0006
0.0008
0.001
0.0012
0 0.1 0.2 0.3
Voltage, mV
Pow
er, m
ASeries1
Nanocrystalline nanoparticle calculations
Assumed size of 20nm: r = 10nm, density TiO2 = 3.84g/cm3
Volume of spherical particle = 4.19 * 10-18 cm3/particleAmount of TiO2=(4.19*10-18)cm3 *3.84g/cm3=1.61 * 10-
17g/particle
SA= 1.26*10-11cm2/particleSA/g = 1.26*10-11/1.61*10-17 = 78m2/gatoms on surface/atoms in volume =
1.26*10-11cm2 * 1015cm2 / 4.19 * 10-18 * 1022.5 = 0.095
Procedure Improvements
• Filter dye
• Don’t get light source too close to photocell while performing data acquisition
• Be sure TiO2 layer is uniform and not too thin