Solvent Free Dye Sensitized Solar Cells

In 1991 Grätzel and o’Regan demonstrated the first example of a photoelectrochemical solar cell, a DNSC (Dye-sensitized Nano-structured Solar Cell), which could deliver a competitive light-to-energy conversion efficiency and promised sufficient stability for mass production. Since then, material scientists have focused upon SAMs (Self Assembled Mono-layers) of metal complexes.

In an update on dye-sensitized solar cell technology, we learn from Green Car Congress that Professor Michael Grätzel has been busy. Swiss researchers at EPFL (École Polytechnique Fédérale de Lausanne) have teamed up with Chinese researchers to achieve a new efficiency benchmark for solvent-free, dye-sensitized solar cells.

Self-Assembled Monolayers
“Shaik Zakeeruddin and colleagues from the Changchun Institute of Applied Chemistry at the Chinese Academy of Sciences (CAS) have achieved a record light conversion efficiency of 8.2% in solvent-free dye-sensitized solar cells.”

When titanium oxide nanocrystals are coated with light-absorbing dye molecules and light strikes the dye, electrons are freed. This process creates areas of positive charge as electrons are lost and the semiconducting titanium dioxide particles have the capacity to collect the electrons to an external circuit, producing an electric current. Instead of using organic solvents as an electrolyte solution, Grätzel and colleagues developed a mixture of three solid salts.

When the three solid components are mixed together in the right proportion they turn into a melt showing excellent stability and efficiency… This breakthrough in efficiency without the use of volatile organic solvents will make it possible to pursue large scale, outdoor practical application of lightweight, inexpensive, flexible dye-sensitized solar films that are stable over long periods of light and heat exposure.

GCC Recommended Resources

  • Yu Bai, Yiming Cao, Jing Zhang, Mingkui Wang, Renzhi Li, Peng Wang, Shaik M. Zakeeruddin & Michael Grätzel, “High-performance dye-sensitized solar cells based on solvent-free electrolytes produced from eutectic melts”, Nature Materials  29 June 2008 doi:10.1038/nmat2224

Other Possibly Related AG Posts Automatically Generated

This entry was written by jcwinnie, posted on 2008-6-30 at 7:44 am, filed under biology, chemistry, design, development, education, energy, factor, physics, research and tagged , , , . Bookmark the permalink. Follow any comments here with the RSS feed for this post. Both comments and trackbacks are currently closed.

3 Comments

  1. jcwinnie
    Posted 2008-6-30 at 3:32 pm | Permalink

    “Tin-based nanocomposites,” notes Nanowerks, can “have very high specific capacity of >800 mAh/g in the initial 10 cycles, and 550 mAh/g after the 100th cycle.”

  2. jcwinnie
    Posted 2008-10-30 at 4:30 pm | Permalink

    Green Car Congress reports that researchers in China and Switzerland have achieved as high as 10% efficiency from new practical dye-sensitized solar cells (DSCs, or Grätzel cells) with low volatility and solvent-free electrolyte.

    In addition to the higher efficiencies, the new cells also showed greater stability at high temperatures than previous formulas, retaining more than 90% of their initial output after 1,000 hours in full sunlight at 60°C. Their study is scheduled for the 13 November issue of ACS’ The Journal of Physical Chemistry C.

    The research, conducted by Dr. Peng Wang of the Chinese Academy of Sciences and colleagues—including Dr. Michaël Grätzel, inventor of the first dye-sensitized solar cell—involves photovoltaic cells composed of titanium dioxide and a new type of ruthenium-based dye that helps boost the light-harvesting ability.

    DSCs are less expensive than standard silicon-based solar cells and can be made into flexible sheets or coatings. Although promising, DSCs have had serious drawbacks, including low conversion efficiencies, a drop in performance after relatively short exposures to sunlight, and the use of toxic and volatile solvents, which require expensive hermetic sealing.

    Using a volatile electrolyte, DSC technology has delivered efficiency of up to 11.0-11.3% measured under the standard air mass 1.5 global (AM 1.5G) sunlight—about half that of the best silicon solar cell. [AM 1.5G is the intensity of insolation equivalent to the sun shining through the atmosphere to sea level, with oxygen and nitrogen absorption, at an oblique angle 48.2 degrees from the vertical (zenith).] Despite the lower efficiencies, the DSCs offer stable output over a moderate temperature range as well a response to weak and diffuse light.

    In the past several years, much work has been focused on the development of practical DSCs by using low-volatility electrolytes, solvent-free ionic liquids, or solid organic hole-transporters. Promoted by material designing together with device engineering, the highest efficiency of a stable device with a low-volatility electrolyte now stands at 9.1%, whereas that of its counterpart with a solvent-free electrolyte is 7.7%.

    Shi et al. (2008)

    Using a nanocrystalline titania film stained with the new ruthenium sensitizer, the researchers achieved 9.6-10.0% and 8.5-9.1% efficiencies in conjunction with low-volatility and solvent-free electrolytes under AM 1.5G solar illumination.

    The research team is working on stability studies of a testing cell at 80° C and long-term evaluations of a large solar panel with the newly developed systems.

    GCC Recommended Resources

    • Dong Shi, Nuttapol Pootrakulchote, Renzhi Li, Jin Guo, Yuan Wang, Shaik M. Zakeeruddin, Michaël Grätzel, and Peng Wang (2008) New Efficiency Records for Stable Dye-Sensitized Solar Cells with Low-Volatility and Ionic Liquid Electrolytes ASAP J. Phys. Chem. C, doi: 10.1021/jp808018h

    • Yu Bai, Yiming Cao, Jing Zhang, Mingkui Wang, Renzhi Li, Peng Wang, Shaik M. Zakeeruddin and Michaël Grätzel (2008) High-performance dye-sensitized solar cells based on solvent-free electrolytes produced from eutectic melts. Nature Materials 7, 626 – 630 doi: 10.1038/nmat2224

  3. jcwinnie
    Posted 2008-11-12 at 2:30 pm | Permalink

    Technology Review also had news about improvements to organic dye (Grätzel) solar cells.


    “Chinese and Swiss researchers announced earlier this week that they have reached the highest efficiency yet for dye-sensitized solar cells (Grätzel cells). The photovoltaic cells are cheaper than silicon-based solar cells, but until this week’s discovery their drawbacks have outweighed their benefits.”

    “While silicon-based solar cells have typical efficiencies of about 12 percent, they are significantly more expensive to produce. And since the prohibitive cost of silicon solar cells prevents many homes and businesses from committing to solar energy, a cheaper solution should be welcomed.”

    Dye-sensitized solar cells, sometimes called Grätzel cells after their inventor, Michael Grätzel, a chemistry professor at the École Polytechnique Fédérale de Lausanne, in Switzerland, have long been considered a promising technology for reducing the cost of solar power. They’re potentially cheaper to make than conventional solar cells and can be quickly printed. But this potential hasn’t been realized because to achieve efficiency levels high enough to compete with conventional solar cells–about 10 percent–it’s been necessary to use volatile electrolytes that need to be carefully sealed inside the cells, an expensive and unreliable step in the manufacturing.

    Now Grätzel, along with Peng Wang, a professor at the Changchun Institute of Applied Chemistry, Chinese Academy of Sciences, have made efficient solar cells that use nonvolatile electrolytes, with the best achieving efficiencies of 10 percent. They also showed that the solar cells remained stable when exposed to light and high temperatures for 1,000 hours. The advance “pushes the technology close to over the ’10 percent hump,’ which is where a thin-film technology needs to be to be economically competitive,” says Tonio Buonassisi, a professor of mechanical engineering at MIT.

    One of the electrolytes is something called an ionic fluid–a fluid largely made up of ions and often composed of salts that have low melting temperatures. An ionic fluid can be used with plastic electrodes, which would allow for solar cells that are both efficient and flexible, and therefore could be incorporated into clothing, awnings, and covers for cars. “We never dreamt that we could have efficiencies of 9 or 10 percent with ionic liquids,” Grätzel says. “Ten years ago, we had 1 percent efficiency, and we never thought it would get any better.”

    The new solar cells were made possible by advances first published this summer. In that work, the researchers increased the conductivity of electrolytes based on ionic fluids and produced solar cells that were 8.2 percent efficient. In the current work, published last month in the Journal of Physical Chemistry, the researchers further increased the efficiency by pairing the ionic liquid electrolyte with a new dye, the part of the dye-sensitized solar cell that absorbs sunlight. The new dye absorbs light far better than the conventional dye. Because the dye absorbs light so well, it’s possible to cut the thickness of the active material in the solar cell in half, which makes it easier for electrons to escape the solar cell and reach an external circuit. That, in turn, increases efficiency, in this case to 9.1 percent.

    The researchers also paired the new dye with a nonvolatile solvent-based electrolyte. It’s not quite as stable as an ionic liquid, and it can’t be used with plastic. But it allowed slightly higher efficiencies–up to 10 percent.

    Grätzel is working with two companies to commercialize this technology. One, G24 Innovations, based in Cardiff, U.K., is planning to sell dye-sensitized solar cells for applications such as recharging cell phones, especially in countries with unreliable electricity. Another company, Dyesol, based in Queanbeyan, Australia, is planning to sell solar cells that can double as the facades on buildings. Both companies have already developed dye-sensitized solar cells based on earlier technology, but the recent advances could make the cells cheaper and significantly improve performance.

2 Trackbacks

  1. By After Gutenberg » Polymer-based Organic Photo Voltaic Technology on 2008-10-10 at 5:49 pm

    [...] companies ready to stock your thin-film solar farm is Konarka Technologies, Inc. The underlying, dye-sensitized, solar cell technology is the result of leadership by 2 materials scientists: 1) the late Dr. Sukant Tripathy, an [...]

  2. By After Gutenberg » Black Silicon on 2008-10-13 at 4:44 pm

    [...] “Another breakthrough, eh? How many does that make so far this [...]

Bad Behavior has blocked 2398 access attempts in the last 7 days.