Organic Solar Power

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Organic Solar Power

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Wed, 18 Jan 2006 15:41:27 +0000

 

 

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http://www.i-sis.org.uk/OSP.php

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ISIS Press Release 18/01/06

 

Organic Solar Power

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Solar power could become the next big thing in homes,

personal accessories, the battlefield and other military

applications. New affordable, durable and portable solar

devices provide local energy generation for maximum

efficiency and minimum greenhouse gas emissions. Dr. Mae-Wan

Ho

 

A fully referenced and illustrated version of this article

is posted on ISIS members' website

http://www.i-sis.org.uk/full/OSPFull.php.

Details here

http://www.i-sis.org.uk/membership.php

 

New materials for harvesting light

 

Organic solar cells emerged in the late 1970s, based on

conjugated polymers – polymers with alternating double and

single carbon-carbon bonds – when it was discovered that

doping these materials - slightly contaminating with

appropriate chemical elements - increased conductivity

several orders of magnitude [1]. Since then electronic

conducting materials based on conjugated polymers have found

many applications including light emission diodes (LEDs) and

solar cells.

 

Nowadays, organic semi-conductors include not only polymers

(molecular mass more than 10 000 atomic mass units), but

also small molecules (molecular mass less than a few

thousand units), and dendrimers, with molecular masses in

between the polymers and small molecules. The distinctions

between the different kinds of molecular semiconductors are

important in determining the processes required in making

films and devices, but the way they work is identical.

 

New mechanisms

 

Organic solar cells work differently from conventional

inorganic semiconductor solar cells. Light absorbed by an

inorganic semiconductor produces free charge carriers –

electrons and holes – that are transported separately

through the semiconductor material. In an organic solar

cell, however, light absorption produces excitons, electron-

hole pairs that are bound together and hence not free to

move separately. To generate free charge carriers, the

excitons must be dissociated. This can happen in the

presence of high electric fields, at a defect site in the

material, or usually, at the interface between two materials

that have a sufficient mismatch in their energy levels.

 

Thus, an organic solar cell can be made with the following

layered structure: positive electrode/electron

donor/electron acceptor/negative electrode. An exciton

created in either the electron donor or electron acceptor

layer can diffuse to the interface between the two, leading

to electron transfer from the donor material to the

acceptor, or hole transfer from the acceptor to the donor.

The negatively charged electron and the positively charged

hole is then transported to the appropriate electrode.

 

Endless new possibilities

 

Organic materials are diverse and versatile, offering

endless possibilities for improving a wide range of

properties such charge generation, separation, molecular

mass, `wettability' (between organic molecules and inorganic

material), bandgap (determining the ability to harvest light

efficiently in different parts of the solar spectrum,

especially the infrared), molecular energy levels, rigidity,

and molecule-to-molecule interactions. Different organic

molecules can be combined with one another, or with

inorganic materials in many unique, favourable formulations.

 

One major advantage of organic solar panels is the low cost

involved in manufacture. Organic molecules are cheap to

make, they can have very high light absorbing capacity so

that films as thin as several hundred nanometres would be

sufficient for the purpose. Organic materials are compatible

with plastic and other flexible substrates; and devices can

therefore be fabricated with low-cost, high throughput

printing techniques that consume less energy and require

less capital investment than silicon-based devices and other

thin-film technologies. One estimate put the reduction in

cost by a factor of 10 or 20 [3]. Consequently, organic

solar cells do not need to have conversion efficiencies as

high as thin-film inorganic solar cells to become

competitive in the market.

 

Organic materials can be printed on in any pattern or

colour, and integrated into existing building structures, or

even clothing or other accessories. In a couple of years, we

are told, it will be possible to recharge one's mobile phone

from one's jumper, or power up one's laptop by plugging into

the beach tent.

 

Seriously these affordable new generations of solar devices

will be a boon for the energy needs of poor countries that

do not have power grids or other infrastructure support.

Generating electricity for use on site also avoids the huge

losses incurred in generating electricity in power stations

and distributing through the grid, estimated to be as high

as 69 percent [3]. This is why local `microgeneration' of

electricity is also gaining favour in developed countries as

a means of improving on efficiency and minimising greenhouse

gas emissions.

 

Plastic solar cells

 

Most organic solar cells are currently running at conversion

efficiencies less than 5 percent. These include flexible

thin-film modules made of light-harvesting organic plastic

polymers.

 

Kornaka Technologies, a company based in Lowell,

Massachusetts, USA, announced the acquisition of Siemens's

organic photovoltaic research activities in September 2004

in order to develop and commercialise new plastic power

cells [4] for " any electronic device or structure to carry

its own on-board source of renewable energy. " Siemens has

its headquarters in Berlin and Munich, and is one of the

world's largest electrical engineering and electronics

company. Konarka cofounder and CEO Howard Burke said that

the company was testing various product applications for

consumer electronics and military devices at its pilot

manufacturing facility in Lowell. However, he would not say

whether the tests have reached the company's stated goal of

10 percent efficiency [5].

 

A year later, Konarka announced a joint research programme

with Evident Technologies, a company based in New York USA,

to develop " ultra high performance plastic solar cells " [6]

that combine its novel polymers with Evident's quantum dot

nanotechnology. The quantum dot power plastic could be used

for " demanding energy, communications and military

applications, such as battlefied or off-grid power

generation. "

 

The Pentagon is hoping to use Konarka's solar cells to

create a tent that can generate electricity from the sun,

and tools that soldiers can carry in the field to recharge

the batteries in their cell phones, night vision scopes, and

global positioning systems.

 

A major problem with the plastic solar cells and organic

solar cells in general is stability and longevity. Apart

from chemical decomposition of the organic molecules,

organic solar devices can degrade from distortion, loss of

adhesion of the layers, or the layers diffusing into each

other. So, careful design of the device and engineering more

stable molecules are needed to substantially improve the

lifetimes of the device. Rapid progress has been made on

these fronts, especially with an organic-inorganic hybrid

solar cell.

 

Dye sensitised solar cells

 

Dye sensitised solar cells (DSSCs) are among the third

generation devices nearest to the market, or already in the

market. These are not purely organic solar cells, but are

made of a hybrid of organic and inorganic semi-conducting

materials.

 

The basic scheme of a DSSC is shown in Fig. 1 [7]. A layer

of light-sensitive dye is attached to the surfaces of the

15-20 nm nanoparticles of TiO2 in a 5-20 microns thick film.

One main effect of the nano-structured film is to greatly

amplify the light-sensitive surface. The actual surface area

in a 10 micron thick film is 1 000 times greater than that

projected; because of the small size of the particles, these

films are highly transparent. To help enhance light

harvesting in the red and near infra-red range, quantum dots

of 100 nm to 400 nm are incorporated into the TiO2 film (see

" Quantum dots and ultra-efficient solar cells " , this

series). The TiO2 film is deposited by screen-printing from

a colloidal suspension and sintered (heated to a high

temperature to fix it).

 

The dye is a member of a class of red ruthenium complexes

code named N3, or N719. The dye-sensitized photocell shows a

broad photon-to-current efficiency – the number of electrons

generated per photon striking the cell - of more than 70

percent between 350 to 660nm. The excited electrons are

injected very rapidly (10-15-10-12 s with 100 percent

quantum efficiency into the conduction band of the TiO2.

(The quantum efficiency is the fraction absorbed by the dye

that is converted into conducting electrons.) Dye

regeneration occurs in 10-12 s, an order of magnitude slower

than electron injection, while charge recombination takes

place even slower, on a millisecond timescale, which means

they do not interfere with efficient charge separation [8].

 

The dye has been optimized for its light absorption

characteristics as well as stability. It is stable enough to

sustain about 108 turnover cycles, corresponding to about 20

years of exposure to natural light, which is longer lasting

than amorphous silicon. The most recent record in power

conversion efficiency set by a cell of this type is 11

percent, in the laboratory of the inventor Dr. Michael

Gratzel in Lausanne Switzerland [7]. This is considerable

progress from an efficiency of 1 to 2 percent reported in

1988.

 

Figure 1. A dye-sensitized solar cell. The gray dots

represent nanoparticles covered with a single layer of dye

(small red dots). Electrons are represented by circled minus

signs, an incident photon absorbed by hv. ECB and EVB are

the energy levels of the conduction band and valence band

respectively, which defines the band gap. Redrawn from [7]

 

Improving stability and efficiency

 

Some recent milestones in improving stability and efficiency

include turning the liquid electrolyte into a gel, thereby

preventing leakage of the electrolyte from the cell. The

cell sustained heating for 1 000h at 80C, maintaining 94

percent of its initial performance. The device also remained

stable under light soaking at 55C for 1 000h in a solar

simulator equipped with an ultraviolet filter. This cell had

a conversion efficiency of more than 6 percent [9].

 

A further improvement of energy conversion efficiency to 8

percent or more [10] was achieved with a cell that retained

over 98 percent of its initial performance after 1 000 h of

accelerated tests including thermal stress at 80C in the

dark or 1 000h of visible light soaking at 60C. This cell

used a robust electrolyte of low volatility in conjunction

with an improved ruthenium dye code-named K-19, grafted

together with the co-absorbent, 1-decylphosphonic acid onto

the TiO2 film.

 

Another new member of the same dye, code named Z-910

absorbed light more completely and over a wider spectral

range [11]. The light conversion efficiency exceeded 80

percent between 470-620 nm, reaching a maximum of 87 percent

at 520 nm. In full sunlight, a DSSC tested had an overall

power conversion efficiency greater than 10.2 percent.

 

Meanwhile, a research team at the National Institute of

Advanced Industrial Science and Technology in Ibaraki,

Japan, found that simply pretreating the TiO2 with

hydrochloric acid was sufficient to significantly improve

the energy conversion efficiency of their DSSC to 10.5

percent [12]. This appeared to be due to increased

efficiency in light-harvesting, electron injection and/or

charge collection. The researchers used another ruthenium

complex, the black dye, with absorption extending into the

near IR region up to 920nm, which gives a theoretical

efficiency of 19.6 percent for the DSSC. There is certainly

plenty of room for improvement, and this will happen

rapidly.

 

In another significant development, Solaris Nanosciences, a

company in Providence, Rhode Island, made the cell

rechargeable [13], thus claiming the lowest manufacturing

cost for a long-life photovoltaic system in the world: less

than $3 000 compared with current silicon technology outlays

of $12 000 or more.

 

The life-time of the cell is extended by a chemical process

that allows the degraded dye in already installed cells to

be removed and replaced with a new dye, restoring the

performance of the original solar cell.

 

The recharging process was independently confirmed at the

Swiss Federal Institute of Technology Lausanne headed by the

inventor Michael Grätzel. " Our evaluation has shown without

doubt that the cell performance after three coloration

cycles remained intact, and could even be pushed beyond the

initial cell output. " He said.

 

The recharging process has the advantage that the cell could

be refilled with new generations of dyes, thus effectively

upgrading the solar cell during its life-time, obviating the

need for total replacement of the expensive equipment,

thereby saving on both the financial and environmental costs

involved.

 

Another advantage of these cells is that they are good for

high latitudes. They do not have the reflectivity of

inorganic materials such as silicon, which allows them to

have greater conversion efficiency when the sun is at high

angles relative to the cell.

 

The Solaris cell is currently running at a conversion

efficiency of seven percent, but Dr. Nabil Lawandy, CEO of

Solaris Nanosciences, is confident that further improvements

are in the pipelines. " We expect the first prototypes to be

through the testing cycle in about 12 months and then we

will be considering a manufacturing strategy with a target

of 1000 panels (20 m2 module) annually for the first

manufacturing plant. " He said.

 

Commercial developments

 

In fact the first commercial products in DSSC have already

appeared [7]. Companies like Konarka in the US, Aisin Seiki

in Japan, RWE in Germany and Solaronix in Switzerland, are

developing new products based on it. Particularly

interesting are applications in construction, such as

electricity generating glass tiles. The Australian company

Sustainable Technologies International has produced such

tiles on a large scale for field-testing, and the first

building has been equipped with a wall of glass tiles.

 

Toxicities

 

Things are moving fast in dye-sensitised and other organic

solar cells; fast enough for people to overlook the serious

toxicities of some of the main components. There is

justification for the opinion that ruthenium dyes, and

indeed all ruthenium compounds are " highly toxic " and

" carcinogenic " [14]. A study published in 2000 indicated

that the N3 ruthenium dye used in the DSSCs is not mutagenic

[15], but its other potential toxicities have not been

investigated.

 

Although conventional TiO2 may be relatively harmless, many

ultrafine nanoparticles (less than 1 micron), such as those

used in DSSCs, are pathogenic [16], and chronic exposure to

the nanoparticles may result in fibrosis and airflow

obstruction in the respiratory tract [17].

 

It is important for proponents and developers of these very

promising solar cells and applications to ensure that

researchers and workers as well as the public are protected

from the hazardous materials, that appropriate containment

and recycling of wastes take place to prevent environmental

pollution, and that research on safety and safe use goes

hand in hand with development and commercial exploitation.

In addition, effort should be devoted to finding safer

alternatives for toxic materials.

 

 

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