20.109(F13): Mod 3 Day 4 Solar cell assembly

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For more information on this method of optimization, please see Dang, Xiangnan, et al. "Tunable Localized Surface Plasmon-Enabled Broadband Light-Harvesting Enhancement for High-Efficiency Panchromatic Dye-Sensitized Solar Cells." Nano letters 13.2 (2013): 637-642.
For more information on this method of optimization, please see Dang, Xiangnan, et al. "Tunable Localized Surface Plasmon-Enabled Broadband Light-Harvesting Enhancement for High-Efficiency Panchromatic Dye-Sensitized Solar Cells." Nano letters 13.2 (2013): 637-642.
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=Electron collection=
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===Electron collection===
While the path of electrons laid out previously is ideal, not all of the electrons leaving the excited dye will enter the semi-conductor and reach the electron collector.  Instead of entering the semi-conductor, the electron ejected from the dye can recombine with the redox mediator or another dye molecule.  Additionally, electrons which have entered the semi-conductor can leave and recombine with the dye or redox mediator surrounding the semi-conductor*.  In order to avoid these unfavorable events, we can decrease the time it takes for electrons to reach the electron collector. Single-walled nanotubes made from sp2 bonded carbon atoms, can form more direct paths for the electrons as the sp2 bonds endow carbon nanotubes with the property of high electron mobility. As a result, our M13 phage fabricated nano-composite of aligned single walled carbon nanotubes coated with TiO2 can improve the performance of a DSSC by providing a way for electrons to reach the electron collector faster, thereby reducing unfavorable recombination events.   
While the path of electrons laid out previously is ideal, not all of the electrons leaving the excited dye will enter the semi-conductor and reach the electron collector.  Instead of entering the semi-conductor, the electron ejected from the dye can recombine with the redox mediator or another dye molecule.  Additionally, electrons which have entered the semi-conductor can leave and recombine with the dye or redox mediator surrounding the semi-conductor*.  In order to avoid these unfavorable events, we can decrease the time it takes for electrons to reach the electron collector. Single-walled nanotubes made from sp2 bonded carbon atoms, can form more direct paths for the electrons as the sp2 bonds endow carbon nanotubes with the property of high electron mobility. As a result, our M13 phage fabricated nano-composite of aligned single walled carbon nanotubes coated with TiO2 can improve the performance of a DSSC by providing a way for electrons to reach the electron collector faster, thereby reducing unfavorable recombination events.   

Revision as of 13:25, 6 November 2013

20.109(F13): Laboratory Fundamentals of Biological Engineering

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DNA Engineering        System Engineering        Biomaterials Engineering              

Contents

Solar Cell Assembly

Today's goal

Use our characterized phage based nano-composites to build DSSC’s.

Solar cells in society

Solar cells have the ability to fill the worlds need for renewable energy in order to create a more sustainable society. Currently, the majority of solar cells on the market are silicon based (90%). Unfortunately, production costs must be lower and or efficiencies must increase in order to compete with fossil fuels in today’s market. New types of solar cells such as CdTe based solar cells are thin film based to allow for ease in manufacturing. Similarly, dye sensitized solar cells (DSSC) have the potential to lower production cost as compared to the traditional silicon based photovoltaics. In addition, DSSC’s provide the opportunity of integration into buildings and consumer products as they are lightweight, flexible, and exhibit better performance in diffuse light than competitors.

DSSC

Dye sensitized solar cells (DSSC’s) function based on the following steps. An image depicting this cycle can be seen on the right.

  1. Dye becomes excited by light.
  2. Dye injects an electron very rapidly to the TiO2 (the conduction band), dye is oxidized in the process.
  3. Electrons are transported through the semi-conducting TiO2, move through the load, and eventually reach the counter electrode.
  4. At counter electrode, normally platinum, the electrons reduce the redox mediator located in the electrolyte of the DSSC.
  5. Redox mediator diffuses to meet and regenerate oxidized dye molecules.

In order for the above process to be completed, five general components must be included in a DSSC. Below is a list of each of these general components, as well as the specific materials we will be using for each in our DSSC’s.

  1. Semi-conductor: TiO2 particles enhanced with either gold or SWNTs via phage bio-templated assembly.
  2. Sensitizer (dye): N719 dye
  3. Electrolyte and redox mediator pair: I3 - / I-
  4. Counter electrode: Pt
  5. Mechanical support: TCO (transparent conducting oxide) coated FTO (Fluorine doped tin oxide) glass. This material will be used as the base of the anode in your DSSC.

For more information on DSSC’s you can look to these resources:

Nazeeruddin, Md K., Etienne Baranoff, and Michael Grätzel. "Dye-sensitized solar cells: A brief overview." Solar Energy 85.6 (2011): 1172-1178.

Hagfeldt, Anders, et al. "Dye-sensitized solar cells." Chemical Reviews 110.11 (2010): 6595-6663.

Our phage improvements

Light collection

In order to improve efficiency of DSSC’s we will be using our gold/titania phage nano-composites to increase the wavelengths of light which excite the dye to eject an electron (also termed increasing “light harvesting”). By increasing the range of light wavelengths which can excite the dye, we will generate more electrons and thus produce more energy. Gold/titania nano-composites increase the range of wavelengths which excite the dye via the interaction of localized surface plasmons (elementary excitation states in the gold nanoparticles) with the dye.

For more information on this method of optimization, please see Dang, Xiangnan, et al. "Tunable Localized Surface Plasmon-Enabled Broadband Light-Harvesting Enhancement for High-Efficiency Panchromatic Dye-Sensitized Solar Cells." Nano letters 13.2 (2013): 637-642.

Electron collection

While the path of electrons laid out previously is ideal, not all of the electrons leaving the excited dye will enter the semi-conductor and reach the electron collector. Instead of entering the semi-conductor, the electron ejected from the dye can recombine with the redox mediator or another dye molecule. Additionally, electrons which have entered the semi-conductor can leave and recombine with the dye or redox mediator surrounding the semi-conductor*. In order to avoid these unfavorable events, we can decrease the time it takes for electrons to reach the electron collector. Single-walled nanotubes made from sp2 bonded carbon atoms, can form more direct paths for the electrons as the sp2 bonds endow carbon nanotubes with the property of high electron mobility. As a result, our M13 phage fabricated nano-composite of aligned single walled carbon nanotubes coated with TiO2 can improve the performance of a DSSC by providing a way for electrons to reach the electron collector faster, thereby reducing unfavorable recombination events.

For more details about how this concept was developed in the Belcher lab, please look to this paper: Dang, Xiangnan, et al. "Virus-templated self-assembled single-walled carbon nanotubes for highly efficient electron collection in photovoltaic devices." Nature nanotechnology 6.6 (2011): 377-384.

  • Kinetics of electron movement are also the reason for selecting semiconductors to collect electrons from the excited dye. The TiO2 (or other semiconductor used in the DSSC) promotes directional flow of electrons in the solar cell. Once injected quickly to the TiO2(10^-12 seconds), electrons are not as easily recombined with the sensitizer or redox mediator (which occurs on a 10^-2, 10^-3second time frame). If instead, the electrons entered a metal, recombination events would be much more frequent.


Protocols

While You Were Out

Ethyl cellulose/Terpineol mixture(left)Final paste (right)
Ethyl cellulose/Terpineol mixture(left)Final paste (right)

The TiO2 mineralized SWNT:phage or SWNT:gold complexes from M2D2 were dried in a vacuum oven at room temperature and ground to micron sized particles via mortar and pestle. After grinding, pure TiO2, ethyl cellulose (binder) and terpineol (an organic solvent with a high boiling point) were added to make a paste.

Additionally, FTO glass was coated with a thin layer of TiO2. This glass will be used as the base of your anode. This was achieved by first cleaning the FTO glass, then incubating the glass in a solution of TiCl4.

Part 1:

Testing for resistance
Testing for resistance
Doctor blading preparation
Doctor blading preparation

  1. Use a resistance meter to determine which side of a prepared glass anode base contains the layer of TiO2 coated FTO. The coated side of interest should have a measurable level of resistance while the pure glass side should not.
  2. With the coated side up, align your glass anode base onto a gridded template containing a 4mm x 4mm square so that the square appears in the center of the base.
  3. Using scotch tape, create a "well" the size of the 4mm X 4mm square by taping everywhere on the glass except the small square. (One piece on each side and one on the top and bottom should suffice.) Because the thickness of the tape is consistent (~50 micrometers), this method is a simple way to make uniformly sized solar cells.
  4. Using a bent pipette tip, paint a small amount of the Titania paste that contains SWNT:Titania powder onto the top of the well. The amount you use should be roughly equivalent to the amount seen on the photo to the right.
  5. Spread the paste evenly throughout the well using the edge of a glass slide. This process is known as "doctor blading." Once spread, let the device sit for about 3 minutes; this helps reduce the surface irregularity of the paste.
  6. Carefully remove the tape from around the well and heat in air at 120deg for 5 min.
  7. Repeat the doctor blading process, and heat again in air at 120deg for 5 min.
  8. Heat in air for 4 hours at 310deg. This step removes the virus and cellulose from the device.
Anode immersed in dye
Anode immersed in dye

(To be completed by TA)

  1. Heat in Argon for 30min at 500deg. This step calcinates the TiO2 nanoparticles, increasing crystalinity as well as connecting the particles to one another (which is important to electron transport in the device).
  2. After letting the device cool from the annealing stage, immerse it in Ru620 dye solution that contains 1:1 acetonitrile and tert-butyl alcohol. This will be left at room temperature until the next lab session where the counter electrode along with the completed device will be assembled and tested.

Part 2:

The groups not visiting the Belcher lab should use the extra time to work on their research proposals. These will be presented/turned in just one week from today! You can review the requirements for the final proposals here (oral presentations) and here (written proposals).

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