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Whenever we think of solar energy, we assume that it is just simple sunlight, ignoring the fact that visible light is just part of the complete electromagnetic spectrum.

It is important to keep in mind that electromagnetic radiation is not monochromatic, it’s made up of a wide range of different wavelengths, and therefore different energy levels.

It is possible to separate light into different wavelengths, which can be seen in the form of a rainbow. And as the light that falls on our solar cell has multiple photons carrying different ranges of energies, some of these photons don’t have enough energy to alter an electron-hole pair.

This means that they’ll simply pass through the cell as if it were transparent. However, other photons may have too much energy. Only a specific amount of energy, which can be measured in electron volts (eV), and is about 1.1 eV for crystalline silicon, is needed to loosen up an electron. This is called the band gap energy of a material.

In case the photon has more energy than the required amount, then this extra energy is lost. Thus if the photon has less energy, or has too much energy, in both the cases energy will be lost. These losses can account for about 70 percent of the radiation energy incident on our cell.

Question arises that why can’t we use a material that has a really low band gap, so we can use more photons? But this is not possible as unfortunately, our band gap also decides the strength (voltage) of our electric field, and if it’s too low, then whatever we make up in extra current through absorbing more photons, we will loose by having a small voltage.

Balancing both these effects, the optimal band gap can be found around 1.4 eV for a cell made from a single material.

However, these aren’t the only losses that we face. The electrons have to flow from one side of the cell to the other through an external circuit. The bottom can be made with a metal which allows good conduction, but if the top is completely covered, then photons can’t get through the opaque conductor and we lose all of our current.

Also, as silicon is a semiconductor, its internal resistance is fairly high, leading to high losses. To minimize these losses, cells are typically covered by a metallic contact grid that shortens the distance that electrons have to travel while covering only a small part of the cell surface. Even after this, some of the photons are blocked by the grid.

Technorati Tags: Energy,Solar,Cell,radiation,voltage,cells,electromagnetic,photons,electron,silicon,photon,electrons

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Human’s curiosity leads towards invention, like utilizing energy from sun and generating electricity. This is a renewable form of energy and is an unlimited resource unlike other resources to generate electricity. This discovery further leads  to invention of appliances and instruments that uses sun rays to generate electricity and when applied  to a large scale  it results in creation of solar power plants.

What is a solar power plant?

A solar power plant captures the sun rays and convert photons into electricity. A solar semi-conductor possess electrons and the  sun ray contains photons. As a  photons  enter  this semi-conductor, these photons are captured and the electrons are transformed into electricity. This mechanism depends on the nature of material being used as semi-conductor.

A solar power plant contains large number of solar panels, that are connected to each other. Basically these panels are electricity generator and generate electric pulses. The electricity produced is then used domestically or for commercial purposes depending on the demand.One can construct a mini power plant by arranging number of solar panels and connecting them.

Efficiency of solar power plant

Its efficiency depends on the intensity of sun rays touching the panels. If more rays are touching the panel, you need few panels to generate electricity and vice verse. Many countries located near equator, have constructed their own solar power plant. These countries avail maximum sunshine by taking advantage of their location and thus make it more efficient. But this doesn’t mean that you are restricted by your location.

You can also build solar power plant  in other parts of the world. Since this technology is in its initial stage, new inventions are in process to make this task easier for other parts of the globe.

Disadvantages of solar power plant

One of the issue related to solar power plant is its space. These solar power plant requires huge space and areas because of their huge size. This size goes on increasing as you are installing more and more panels to enhance its capacity. But, in many countries this issue is resolved by installing mini solar plants. Another issue is its initial development cost. There are huge costs associated with this technology, which makes it unaffordable.

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Silicon, used to make some of the earliest photovoltaic (PV) devices—is still the most popular material for solar cells.Silicon must be refined to a purity of 99.9999%. In single-crystal silicon, the molecular structure—which is the arrangement of atoms in the material—is uniform, because the entire structure is grown from the same crystal. This uniformity is ideal for transferring electrons efficiently through the material.

To make an effective PV cell, however, silicon has to be “doped” with other elements to make it N-type and P-type. The crystalline of a material indicates how perfectly ordered the atoms are in the crystal structure. Silicon, as well as other solar cell semiconductor materials, can come in various forms: single-crystalline, multi crystalline, polycrystalline, or amorphous. In a single-crystal material, the atoms making up the framework of the crystal are repeated in a very regular, orderly manner from layer to layer.

Classification:

In contrast, in a material composed of numerous smaller crystals, the orderly arrangement is disrupted moving from one crystal to another. One classification scheme for silicon uses approximate crystal size and also includes the methods typically used to grow or deposit such material. The absorption coefficient of a material indicates how far light having a specific wavelength (or energy) can penetrate the material before being absorbed. A small absorption coefficient means that light is not readily absorbed by the material. Again, the absorption coefficient of a solar cell depends on two factors: the material making up the cell, and the wavelength or energy of the light being absorbed.

Solar cell material has an abrupt edge in its absorption coefficient. The reason is that light whose energy is below the material’s bandgap cannot free an electron. And so, it isn’t absorbed. The bandgap of a semiconductor material is an amount of energy. Specifically, it’s the minimum energy needed to move an electron from its bound state within an atom to a free state. This free state is where the electron can be involved in conduction. The lower energy level of a semiconductor is called the “valence band.

And the higher energy level where an electron is free to roam is called the “conduction band.” The bandgap (often symbolized by EG) is the energy difference between the conduction band and valence band. N-Type Silicon – N-type silicon is created by doping (contaminating) the Si with compounds that contain one more valence electrons* than Si does, such as with either Phosphorus or Arsenic. Since only four electrons are required to bond with the four adjacent silicon atoms, the fifth valence electron is available for conduction.

P-type

silicon is created by doping with compounds containing one less valence electrons* than Si does, such as with Boron. When silicon (four valence electrons) is doped with atoms that have one less valence electrons (three valence electrons), only three electrons are available for bonding with four adjacent silicon atoms, therefore an incomplete bond (hole) exists which can attract an electron from a nearby atom. Filling one hole creates another hole in a different SI atom. This movement of holes is available for conduction. The photon’s energy transfers to the valence electron of an atom in the N-type SI layer. That energy allows the valence electron to escape its orbit leaving behind a hole.

N-type

silicon layer, the free electrons are called majority carriers whereas the holes are called minority carriers. As the term “carrier” implies, both are able to move throughout the silicon layer of the solar cell, in the P-type silicon layer, electrons are termed minority carriers and holes are termed majority carriers, The region in the solar cell where the N-type and P-type Si layers meet is called the P-N junction. As you may have already guessed, the P-type silicon layer contains more positive charges, called holes, and the N-type silicon layer contains more negative charges, or electrons.

When P-type and N-type materials are placed in contact with each other, current will flow readily in one direction (forward biased) but not in the other (reverse biased). An interesting interaction occurs at the P-N junction of a darkened solar cell. Extra valence electrons in the N-type layer move into the P-type layer filling the holes in the P-type layer forming what is called a depletion zone.

The depletion zone does not contain any mobile positive or negative charges. Moreover, this zone keeps other charges from the P-type and N-type layers from moving across it. So, to recap, a region depleted of carriers is left around the junction, and a small electrical imbalance exists inside the solar cell. This electrical imbalance amounts to about 0.6 to 0.7 volts. So due to the P-N junction, a built in electric field is always present across the solar cell. When photons hit the solar cell, freed electrons (-) attempt to unite with holes on the P-type layer.

The P-N junction

A one-way road, only allows the electrons to move in one direction. If we provide an external conductive path, electrons will flow through this path to their original (P-type) side to unite with holes. The electron flow provides the current ( I ), and the cell’s electric field causes a voltage ( V ). With both current and voltage, we have power ( P ), which is just the product of the two. Therefore, when an external load (such as an electric bulb) is connected between the front and back contacts, electricity flows in the cell, working for us along the way.

This electric field works as a diode, which allow electrons to flow from the P side to the N side, but not to other way around.

The basic concepts of solar cells and the requirements for photovoltaic solar energy conversion are reviewed. All present solar cells are found to follow the same principles. they consist of an absorber embedded between layers with selective transport properties, semi permeable membranes for electrons on one side and for holes on the other side. Their structure is shown to be a consequence of the absorption and transport properties of the materials.

Good transport properties of the absorber allow planar geometries as in Si solar cells, whereas bad transport properties require an interpenetration of the semi-permeable membranes as in the Graetzel cell or the organic solar cell.

Technorati Tags: Solar,Cell,Silicon,crystal,voltage,cells,atoms,photovoltaic,electrons,

crystalline,semiconductor,electron,electrical

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Photovoltaic (PV) cells consist of two semi-conductor layers. One layer containing attracting positive charge, the other attracting negative charge.

Photons are those small particles of solar energy that are emitted by sunlight. Photons that are emitted by sunlight are then engrossed by the solar cells.

Once sufficient photons are attracted towards the negative layer of the photovoltaic cell, they transfer automatically to the positive layer. This happens because the manufacturing process of a positive layer is designed in such a manner.

The connection of these two layers to the external load results in the flow of current and production of electricity. Every single solar energy cell generates approximately 1-2 watts of power.

In order to improve the power output, cells are collected together in a weather-tight package called a solar module. These solar modules which vary from few to many are then wired in parallel direction or in serial to each other. This is called solar array. The purpose of this is to generate required voltage and maximum output needed.

Solar cells are not only environmental friendly but also cost effective because semi-conductor material that PV cells are mainly made of is silicon and silicon can be produced in great quantity naturally. Moreover, there is no maintenance cost because of zero usage of fuel or any other costly components.

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Solar panels preparation is a process that is carried out in delicate manner. This is the reason that most of the time the processes that are carried do not work for long time, till the time when enhancements were made and the semiconductors were made of better substances that gave life to solar panels. This changed the routine and the solar panels worked more efficiently also that they have turned affordable.

Solar Panels (Crystalline Silicon):

These type of solar panels are made of thin, finely slices silicon disks that have thickness less then a centimeter. These thin defined disks are sensitive and treated with care, polished and cared from any damage through slicing process. After the disks are polished they are being added with the semi conductors.

The conductors are so well spread over the disks in a grid-matrix manner and so well spread on the top of the solar panel. Solar panels are protected from damage by bonding a thin layer of glass over it. After the glass sheet is spread it is then cemented with a substrate with a semi conductor expensive cement. This is beneficial as the cement makes the solar panel avoid from extra absorbing of solar heat, as above normal heat if absorbs looses the efficiency of the solar cells. As far the the making itself is done with care to prolong the life of solar cell, but still further steps should be taken when placing a solar panel in a place where it is airy and cool so that the device remains normal for longer time period.

Solar Panels (Amorphous Silicon):

These type of solar panels are contrary to the crystalline solar panels. These solar panels have strong photovoltaic cells and work efficiently. Its structure, performance and lining is totally different solar panels. The process involved in making this kind of solar panels is roll to roll process by repeatedly vaporizing silicon alloys in multiple layers. The good point is that process carries ending in thin layers that helps in absorption of the solar heat. This results in total as great working efficiency and decreased materials prices. The Amorphous solar panels or the A-si solar panels are thinner than the silicon crystalline solar panels. The making of Amorphous silicon solar panels involves less risk of damaging and are less sensitive as compared to making of any other solar panels thus investing money in these photovoltaic cells are still feasible.

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