The word Photovoltaic
is a combination of the Greek word for Light and the name
of the physicist Allesandro Volta. It identifies the
direct conversion of sunlight into energy by means of
solar cells. The conversion process is based on the
photoelectric effect discovered by Alexander Bequerel in 1839.
The photoelectric effect describes the release of positive and
negative charge carriers in a solid state when light strikes
its surface.
How Does a Solar Cell Work?
Solar cells are composed of various
semiconducting materials. Semiconductors are materials,
which become electrically conductive when supplied with
light or heat, but which operate as insulators at low
temperatures.
Over 95% of all the solar cells produced worldwide
are composed of the semiconductor material Silicon (Si). As the second
most abundant element in earth`s crust, silicon has the advantage, of
being available in sufficient quantities, and additionally processing
the material does not burden the environment. To produce a solar
cell, the semiconductor is contaminated or "doped". "Doping" is the
intentional introduction of chemical elements, with which one can obtain
a surplus of either positive charge carriers (p-conducting
semiconductor layer) or negative charge carriers (n-conducting
semiconductor layer) from the semiconductor material. If two
differently contaminated semiconductor layers are combined, then a
so-called p-n-junction results on the boundary of the layers.
- model of a crystalline solar cell
At this junction, an interior electric field is
built up which leads to the separation of the charge carriers
that are released by light. Through metal contacts, an electric
charge can be tapped. If the outer circuit is closed, meaning a
consumer is connected, then direct current flows.
Silicon cells are approximately 10 cm by 10 cm large
(recently also 15 cm by 15 cm). A transparent anti-reflection
film protects the cell and decreases reflective loss on the cell
surface.
Characteristics of a Solar Cell
- current-voltage line of a si-solar cell
The usable voltage from solar cells depends on
the semiconductor material. In silicon it amounts to
approximately 0.5 V. Terminal voltage is only weakly dependent
on light radiation, while the current intensity increases with
higher luminosity. A 100 cm² silicon cell, for example, reaches a
maximum current intensity of approximately 2 A when radiated by 1000
W/m².
The output (product of electricity and voltage) of a
solar cell is temperature dependent. Higher cell temperatures
lead to lower output, and hence to lower efficiency. The level of
efficiency indicates how much of the radiated quantity of light is
converted into useable electrical energy.
Different Cell Types
One can distinguish three cell types according to
the type of crystal: monocrystalline, polycrystalline
and amorphous. To produce a monocrystalline silicon cell,
absolutely pure semiconducting material is necessary.
Monocrystalline rods are extracted from melted silicon and then
sawed into thin plates. This production process guarantees a
relatively high level of efficiency.
The production of polycrystalline cells is more cost-efficient. In this process, liquid silicon is poured into blocks that are subsequently sawed into plates. During solidification of the material, crystal structures of varying sizes are formed, at whose borders defects emerge. As a result of this crystal defect, the solar cell is less efficient.
If a silicon film is deposited on glass or another substrate material, this is a so-called amorphous or thin layer cell. The layer thickness amounts to less than 1µm (thickness of a human hair: 50-100 µm), so the production costs are lower due to the low material costs. However, the efficiency of amorphous cells is much lower than that of the other two cell types. Because of this, they are primarily used in low power equipment (watches, pocket calculators) or as facade elements.
The production of polycrystalline cells is more cost-efficient. In this process, liquid silicon is poured into blocks that are subsequently sawed into plates. During solidification of the material, crystal structures of varying sizes are formed, at whose borders defects emerge. As a result of this crystal defect, the solar cell is less efficient.
If a silicon film is deposited on glass or another substrate material, this is a so-called amorphous or thin layer cell. The layer thickness amounts to less than 1µm (thickness of a human hair: 50-100 µm), so the production costs are lower due to the low material costs. However, the efficiency of amorphous cells is much lower than that of the other two cell types. Because of this, they are primarily used in low power equipment (watches, pocket calculators) or as facade elements.
Material
|
Level of efficiency in % Lab
|
Level of efficiency in % Production
|
|---|---|---|
Monocrystalline Silicon
|
approx. 24
|
14 to17
|
Polycrystalline Silicon
|
approx. 18
|
13 to15
|
Amorphous Silicon
|
approx. 13
|
5 to7
|
From the Cell to the Module
In order to make the appropriate voltages and
outputs available for different applications, single
solar cells are interconnected to form larger units. Cells
connected in series have a higher voltage, while those
connected in parallel produce more electric current. The
interconnected solar cells are usually embedded in transparent
Ethyl-Vinyl-Acetate, fitted with an aluminum or stainless steel
frame and covered with transparent glass on the front side.
The typical power ratings of such solar modules are
between 10 Wpeak and 100 Wpeak. The characteristic data
refer to the standard test conditions of 1000 W/m² solar
radiation at a cell temperature of 25° Celsius. The
manufacturer's standard warranty of ten or more years is
quite long and shows the high quality standards and life
expectancy of today's products.
Natural Limits of Efficiency
- Theoretical maximum levels of efficiency of various solar cells at standard conditions
In addition to optimizing the production
processes, work is also being done to increase the level of
efficiency, in order to lower the costs of solar cells.
However, different loss mechanisms are setting limits on
these plans. Basically, the different semiconductor
materials or combinations are suited only for specific spectral ranges.
Therefore a specific portion of the radiant energy cannot
be used, because the light quanta (photons) do not have
enough energy to "activate" the charge carriers. On the
other hand, a certain amount of surplus photon energy is
transformed into heat rather than into electrical energy.
In addition to that, there are optical losses, such as the shadowing
of the cell surface through contact with the glass surface or
reflection of incoming rays on the cell surface. Other loss
mechanisms are electrical resistance losses in the
semiconductor and the connecting cable. The disrupting
influence of material contamination, surface effects and
crystal defects, however, are also significant.
Single loss mechanisms (photons with too little energy are not absorbed, surplus photon energy is transformed into heat) cannot be further improved because of inherent physical limits imposed by the materials themselves. This leads to a theoretical maximum level of efficiency, i.e. approximately 28% for crystal silicon.
Single loss mechanisms (photons with too little energy are not absorbed, surplus photon energy is transformed into heat) cannot be further improved because of inherent physical limits imposed by the materials themselves. This leads to a theoretical maximum level of efficiency, i.e. approximately 28% for crystal silicon.
New Directions
Surface structuring to reduce reflection loss:
for example, construction of the cell surface in a
pyramid structure, so that incoming light hits the
surface several times. New material: for example, gallium
arsenide (GaAs), cadmium telluride (CdTe) or copper
indium selenide (CuInSe²).
Tandem or stacked cells: in order
to be able to use a wide spectrum of radiation,
different semiconductor materials, which are suited for
different spectral ranges, will be arranged one on top
of the other.
Concentrator cells: A higher light
intensity will be focussed on the solar cells by the use
of mirror and lens systems. This system tracks the sun,
always using direct radiation.
MIS Inversion Layer cells: the
inner electrical field are not produced by a p-n
junction, but by the junction of a thin oxide layer to a
semiconductor.
Grätzel cells: Electrochemical liquid cells with titanium dioxide as electrolytes and dye to improve light absorption.
source: http://www.solarserver.com
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