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Copper indium gallium selenide solar cell

January 01, 1970

A copper indium gallium selenide solar cell (or CIGS cell, sometimes CI(G)S or CIS cell) is a thin-film solar cell used to convert sunlight into electric power. It is manufactured by depositing a thin layer of copper indium gallium selenide solid solution on glass or plastic backing, along with electrodes on the front and back to collect current. Because the material has a high absorption coefficient and strongly absorbs sunlight, a much thinner film is required than of other semiconductor materials.

CIGS cell on a flexible plastic backing. Other architectures use rigid CIGS panels sandwiched between two panes of glass.

CIGS is one of three mainstream thin-film photovoltaic (PV) technologies, the other two being cadmium telluride and amorphous silicon. Like these materials, CIGS layers are thin enough to be flexible, allowing them to be deposited on flexible substrates. However, as all of these technologies normally use high-temperature deposition techniques, the best performance normally comes from cells deposited on glass, even though advances in low-temperature deposition of CIGS cells have erased much of this performance difference. CIGS outperforms polysilicon at the cell level, however its module efficiency is still lower, due to a less mature upscaling.[1]

Thin-film market share is stagnated at around 15 percent, leaving the rest of the PV market to conventional solar cells made of crystalline silicon. In 2013, the market share of CIGS alone was about 2 percent and all thin-film technologies combined fell below 10 percent.[2] CIGS cells continue being developed, as they promise to reach silicon-like efficiencies, while maintaining their low costs, as is typical for thin-film technology.[3] Prominent manufacturers of CIGS photovoltaics were the now-bankrupt companies Nanosolar and Solyndra. Current market leader is the Japanese company Solar Frontier, with Global Solar and GSHK Solar also producing solar modules free of any heavy metals such as cadmium and/or lead.[4] Many CIGS solar panel manufacturer companies have gone bankrupt.[5]

Properties edit

CIGS is a I-III-VI2 compound semiconductor material composed of copper, indium, gallium, and selenium. The material is a solid solution of copper indium selenide (often abbreviated "CIS") and copper gallium selenide, with a chemical formula of CuInxGa(1−x)Se2, where the value of x can vary from 1 (pure copper indium selenide) to 0 (pure copper gallium selenide). It is a tetrahedrally bonded semiconductor, with the chalcopyrite crystal structure. The bandgap varies continuously with x from about 1.0 eV (for copper indium selenide) to about 1.7 eV (for copper gallium selenide).[6]

 
Figure 1: Structure of a CIGS device. CdS is used optionally and some CIGS cells contain no cadmium at all.[7]

CIGS has an exceptionally high absorption coefficient of more than 105/cm for 1.5 eV and higher energy photons.[8] CIGS solar cells with efficiencies around 20% have been claimed by the National Renewable Energy Laboratory (NREL), the Swiss Federal Laboratories for Materials Science and Technology (Empa), and the German Zentrum für Sonnenenergie und Wasserstoff Forschung (ZSW) (translated: Center for Solar Energy and Hydrogen Research), which is the record to date for any thin film solar cell.[9][10] In 2024 a CIGS efficiency record of 23.64% was claimed.[11]

All high performance CIGS absorbers in solar cells have similarities independent of production technique. First, they are polycrystalline α-phase which has the chalcopyrite crystal structure shown in Figure 3. The second property is an overall Cu deficiency.[12] Cu deficiency increases the majority carrier (hole) concentration by increasing the number of (electron-accepting) Cu vacancies. When CIGS films are In rich (Cu deficient) the film's surface layer forms an ordered defect compound (ODC) with a stoichiometry of Cu(In,Ga)
3Se
5. The ODC is n-type, forming a p-n homojunction in the film at the interface between the α phase and the ODC. The recombination velocity at the CIGS/CdS interface is decreased by the homojunction's presence. The drop in interface recombination attributable to ODC formation is demonstrated by experiments which have shown that recombination in the bulk of the film is the main loss mechanism in Cu deficient films, while in Cu rich films the main loss is at the CIGS/CdS interface.[12][13]

 
Figure 3: CIGS unit cell. Red = Cu, Yellow = Se, Blue = In/Ga

Sodium incorporation is necessary for optimal performance. Ideal Na concentration is considered to be approximately 0.1%. Na is commonly supplied by the soda-lime glass substrate, but in processes that do not use this substrate the Na must be deliberately added. Na's beneficial effects include increases in p-type conductivity, texture, and average grain size. Furthermore, Na incorporation allows for performance to be maintained over larger stoichiometric deviations.[8] Simulations have predicted that Na on an In site creates a shallow acceptor level and that Na serves to remove In on Cu defects (donors), but reasons for these benefits are controversial. Na is also credited with catalyzing oxygen absorption. Oxygen passivates Se vacancies that act as compensating donors and recombination centers.

Alloying CIS (CuInSe2) with CGS (CuGaSe2) increases the bandgap. To reach the ideal bandgap for a single junction solar cell, 1.5 eV, a Ga/(In+Ga) ratio of roughly 0.7 is optimal. However, at ratios above ~0.3, device performance drops off. Industry currently targets the 0.3 Ga/(In+Ga) ratio, resulting in bandgaps between 1.1 and 1.2 eV. The decreasing performance has been postulated to be a result of CGS not forming the ODC, which is necessary for a good interface with CdS.[12]

The highest efficiency devices show substantial texturing, or preferred crystallographic orientation. A (204) surface orientation is observed in the best quality devices.[8] A smooth absorber surface is preferred to maximize the ratio of the illuminated area to the area of the interface. The area of the interface increases with roughness while illuminated area remains constant, decreasing open-circuit voltage (VOC). Studies have also linked an increase in defect density to decreased VOC. Recombination in CIGS has been suggested to be dominated by non-radiative processes. Theoretically, recombination can be controlled by engineering the film, and is extrinsic to the material.[14]

Structure edit

The most common device structure for CIGS solar cells is shown in the diagram (see Figure 1: Structure of a CIGS device). Soda-lime glass of about of 1–3 millimetres thickness is commonly used as a substrate, because the glass sheets contains sodium, which has been shown to yield a substantial open-circuit voltage increase,[15] notably through surface and grain boundary defects passivation.[16] However, many companies are also looking at lighter and more flexible substrates such as polyimide or metal foils.[17] A molybdenum (Mo) metal layer is deposited (commonly by sputtering) which serves as the back contact and reflects most unabsorbed light back into the CIGS absorber. Following molybdenum deposition a p-type CIGS absorber layer is grown by one of several unique methods. A thin n-type buffer layer is added on top of the absorber. The buffer is typically cadmium sulfide (CdS) deposited via chemical bath deposition. The buffer is overlaid with a thin, intrinsic zinc oxide layer (i-ZnO) which is capped by a thicker, aluminium (Al) doped ZnO layer. The i-ZnO layer is used to protect the CdS and the absorber layer from sputtering damage while depositing the ZnO:Al window layer, since the latter is usually deposited by DC sputtering, known as a damaging process.[18] The Al doped ZnO serves as a transparent conducting oxide to collect and move electrons out of the cell while absorbing as little light as possible.

The CuInSe2-based materials that are of interest for photovoltaic applications include several elements from groups I, III and VI in the periodic table. These semiconductors are especially attractive for solar applications because of their high optical absorption coefficients and versatile optical and electrical characteristics, which can in principle be manipulated and tuned for a specific need in a given device.[19]

Conversion efficiency edit

 
Solar cell efficiencies of various technologies as tracked by NREL, with CIGS progress in green

CIGS is mainly used in the form of polycrystalline thin films. The best efficiency achieved as of September 2014 was 21.7%.[20] A team at the National Renewable Energy Laboratory achieved 19.9%, a record at the time,[21] by modifying the CIGS surface and making it look like CIS.[22] These examples were deposited on glass, which meant the products were not mechanically flexible. In 2013, scientists at the Swiss Federal Laboratories for Materials Science and Technology developed CIGS cells on flexible polymer foils with a new record efficiency of 20.4%.[23] These display both the highest efficiency and greatest flexibility.

The U.S. National Renewable Energy Laboratory confirmed 13.8% module efficiency of a large-area (meter-square) production panel, and 13% total-area (and 14.2% aperture-area) efficiency with some production modules.[22] In September 2012 the German Manz AG presented a CIGS solar module with an efficiency of 14.6% on total module surface and 15.9% on aperture, which was produced on a mass production facility.[24] MiaSolé obtained a certified 15.7% aperture-area efficiency on a 1m2 production module,[25] and Solar Frontier claimed a 17.8% efficiency on a 900 cm2 module.[26]

Higher efficiencies (around 30%) can be obtained by using optics to concentrate the incident light. The use of gallium increases the optical band gap of the CIGS layer as compared to pure CIS, thus increasing the open-circuit voltage.[22][27] Gallium's relative abundance, compared to indium, lowers costs.

Lab record CIGS efficiencies by substrate(a)
Substrate Glass Steel Aluminium Polymer
Efficiency 22.9% 17.7% 16.2% 20.4%
Institute Solar Frontier (b) Empa Empa Empa
Source: Swissolar, Flisom – presentation November 2014[28]
Note: (a) lab cell with ~0.5 cm2(b)http://www.solar-frontier.com/eng/news/2017/1220_press.html

Comparison edit

Conventional crystalline silicon edit

Unlike conventional crystalline silicon cells based on a homojunction, the structure of CIGS cells is a more complex heterojunction system. A direct bandgap material, CIGS has very strong light absorption and a layer of only 1–2 micrometers (μm) is enough to absorb most of the sunlight. By comparison, a much greater thickness of about 160–190 μm is required for crystalline silicon.

The active CIGS-layer can be deposited in a polycrystalline form directly onto molybdenum (Mo) coated on a variety of several different substrates such as glass sheets, steel bands and plastic foils made of polyimide. This uses less energy than smelting large amounts of quartz sand in electric furnaces and growing large crystals, necessary for conventional silicon cells, and thus reduces its energy payback time significantly. Also unlike crystalline silicon, these substrates can be flexible.[29]

In the highly competitive PV industry, pressure increased on CIGS manufacturers, leading to the bankruptcy of several companies, as prices for conventional silicon cells declined rapidly in recent years. However, CIGS solar cells have become as efficient as multicrystalline silicon cells—the most common type of solar cells. CIGS and CdTe-PV remain the only two commercially successful thin-film technologies in a globally fast-growing PV market.

Other thin films edit

In photovoltaics "thinness" generally is in reference to so-called "first generation" high-efficiency silicon cells, which are manufactured from bulk wafers hundreds of micrometers thick.[30] Thin films sacrifice some light gathering efficiency but use less material.[31] In CIGS the efficiency tradeoff is less severe than in silicon. The record efficiencies for thin film CIGS cells are slightly lower than that of CIGS for lab-scale top performance cells. In 2008, CIGS efficiency was by far the highest compared with those achieved by other thin film technologies such as cadmium telluride photovoltaics (CdTe) or amorphous silicon (a-Si).[21] CIS and CGS solar cells offer total area efficiencies of 15.0% and 9.5%,[32] respectively. In 2015, the gap with the other thin film technologies has been closed, with record cell efficiencies in laboratories of 21.5% for CdTe (FirstSolar) and 21.7% for CIGS (ZSW). (See also NREL best research cell efficiency chart.[33])

Production edit

Film production edit

The most common vacuum-based process is to co-evaporate or co-sputter copper, gallium, and indium onto a substrate at room temperature, then anneal the resulting film with a selenide vapor. An alternative process is to co-evaporate copper, gallium, indium and selenium onto a heated substrate.

A non-vacuum-based alternative process deposits nanoparticles of the precursor materials on the substrate and then sinters them in situ. Electroplating is another low cost alternative to apply the CIGS layer.

The following sections outline the various techniques for precursor deposition processing, including sputtering of metallic layers at low temperatures, printing of inks containing nanoparticles, electrodeposition, and a technique inspired by wafer-bonding.

Selenization edit

The Se supply and selenization environment is important in determining the properties and quality of the film. When Se is supplied in the gas phase (for example as H2Se or elemental Se) at high temperatures, the Se becomes incorporated into the film by absorption and subsequent diffusion. During this step, called chalcogenization, complex interactions occur to form a chalcogenide. These interactions include formation of Cu-In-Ga intermetallic alloys, formation of intermediate metal-selenide binary compounds and phase separation of various stoichiometric CIGS compounds. Because of the variety and complexity of the reactions, the properties of the CIGS film are difficult to control.[8]

The Se source affects the resulting film properties. H2Se offers the fastest Se incorporation into the absorber; 50 at% Se can be achieved in CIGS films at temperatures as low as 400 °C. By comparison, elemental Se only achieves full incorporation with reaction temperatures above 500 °C. Films formed at lower temperatures from elemental Se were Se deficient, but had multiple phases including metal selenides and various alloys. Use of H2Se provides the best compositional uniformity and the largest grain sizes. However, H2Se is highly toxic and is classified as an environmental hazard.

Sputtering of metallic layers followed by selenization edit

In this method a metal film of Cu, In and Ga is sputtered at or near room temperature and reacted in a Se atmosphere at high temperature. This process has higher throughput than coevaporation and compositional uniformity can be more easily achieved.

Sputtering a stacked multilayer of metal – for example a Cu/In/Ga/Cu/In/Ga... structure – produces a smoother surface and better crystallinity in the absorber compared to a simple bilayer (Cu-Ga alloy/In) or trilayer (Cu/In/Ga) sputtering. These attributes result in higher efficiency devices, but forming the multilayer is a more complicated deposition process and did not merit the extra equipment or the added process complexity.[12] Additionally, the reaction rates of Cu/Ga and Cu/In layers with Se are different. If the reaction temperature is not high enough, or not held long enough, CIS and CGS form as separate phases.

Companies currently that used similar processes include Showa Shell, Avancis, Miasolé, Honda Soltec, and Energy Photovoltaics (EPV).[34] Showa Shell sputtered a Cu-Ga alloy layer and an In layer, followed by selenization in H2Se and sulfurization in H2S. The sulfurization step appears to passivate the surface in a way similar to CdS in most other cells. Thus, the buffer layer used is Cd-free, eliminating any environmental impact of Cd. Showa Shell reported a maximum module efficiency of 13.6% with an average of 11.3% for 3600 cm2 substrates.[17] Shell Solar uses the same technique as Showa Shell to create the absorber; however, their CdS layer comes from chemical vapor deposition. Modules sold by Shell Solar claim 9.4% module efficiency.

Miasole had procured venture capital funds for its process and scale up. A record 17.4% aperture efficiency module was confirmed by Fraunhofer in 2019.[35]

EPV uses a hybrid between coevaporation and sputtering in which In and Ga are evaporated in a Se atmosphere. This is followed by Cu sputtering and selenization. Finally, In and Ga are again evaporated in the presence of Se. Based on Hall measurements, these films have a low carrier concentration and relatively high mobility. EPV films have a low defect concentration.

Chalcogenization of particulate precursor layers edit

In this method, metal or metal-oxide nanoparticles are used as the precursors for CIGS growth. These nanoparticles are generally suspended in a water based solution and then applied to large areas by various methods, such as printing. The film is then dehydrated and, if the precursors are metal-oxides, reduced in a H2/N2 atmosphere. Following dehydration, the remaining porous film is sintered and selenized at temperatures greater than 400 °C.[12][14][36]

Nanosolar and International Solar Electric Technology (ISET) unsuccessfully attempted to scale up this process.[17] ISET uses oxide particles, while Nanosolar did not discuss its ink. The advantages of this process include uniformity over large areas, non-vacuum or low-vacuum equipment and adaptability to roll-to-roll manufacturing. When compared to laminar metal precursor layers, sintered nanoparticles selenize more rapidly. The increased rate is a result of the greater surface area associated with porosity. Porosity produces rougher absorber surfaces. Use of particulate precursors allows for printing on a large variety of substrates with materials utilization of 90% or more. Little research and development supported this technique.

Nanosolar reported a cell (not module) efficiency of 14%, however this was not verified by any national laboratory testing, nor did they allow onsite inspections. In independent testing[14] ISET's absorber had the 2nd lowest efficiency at 8.6%. However, all the modules that beat ISET's module were coevaporated, a process which has manufacturing disadvantages and higher costs. ISET's sample suffered most from low VOC and low fill factor, indicative of a rough surface and/or a high number of defects aiding recombination. Related to these issues, the film had poor transport properties including a low Hall mobility and short carrier lifetime.

Electrodeposition followed by selenization edit

Precursors can be deposited by electrodeposition. Two methodologies exist: deposition of elemental layered structures and simultaneous deposition of all elements (including Se). Both methods require thermal treatment in a Se atmosphere to make device quality films. Because electrodeposition requires conductive electrodes, metal foils are a logical substrate. Electrodeposition of elemental layers is similar to the sputtering of elemental layers.

Simultaneous deposition employs a working electrode (cathode), a counter electrode (anode), and a reference electrode as in Figure 4. A metal foil substrate is used as the working electrode in industrial processes. An inert material provides the counter electrode, and the reference electrode measures and controls the potential. The reference electrode allows the process to be performed potentiostatically, allowing control of the substrate's potential.[12]

 
Figure 4: CIGS electrodeposition apparatus

Simultaneous electrodeposition must overcome the fact that the elements' standard reduction potentials are not equal, causing preferential deposition of a single element. This problem is commonly alleviated by adding countering ions into solution for each ion to be deposited (Cu2+, Se4+, In3+, and Ga3+), thus changing that ion's reduction potential. Further, the Cu-Se system has a complicated behavior and the film's composition depends on the Se4+/Cu2+ ion flux ratio which can vary over the film surface. This requires the precursor concentrations and deposition potential to be optimized. Even with optimization, reproducibility is low over large areas due to composition variations and potential drops along the substrate.

The resulting films have small grains, are Cu-rich, and generally contain Cu2−xSex phases along with impurities from the solution. Annealing is required to improve crystallinity. For efficiencies higher than 7%, a stoichiometry correction are required. The correction was originally done via high temperature physical vapor deposition, which is not practical in industry.

Solopower is currently producing cells with >13.7% conversion efficiency as per NREL.[37]

Precursor combination by wafer-bonding inspired technique edit

 
Figure 5: Schematic of wafer-bonding inspired technique

In this process, two different precursor films are deposited separately on a substrate and a superstrate. The films are pressed together and heated to release the film from the reusable superstrate, leaving a CIGS absorber on the substrate (Figure 5). Heliovolt patented this procedure and named it the FASST process. In principle, the precursors can be deposited at low temperature using low-cost deposition techniques, lowering module cost. However, the first generations of products use higher temperature PVD methods and do not achieve full cost cutting potential. Flexible substrates could eventually be used in this process.

Typical film characteristics are not known outside of the company, as no research has been conducted by independently funded laboratories. However, Heliovolt claimed a top cell efficiency of 12.2%.

Coevaporation edit

Coevaporation, or codeposition, is the most prevalent CIGS fabrication technique. Boeing's coevaporation process deposits bilayers of CIGS with different stoichiometries onto a heated substrate and allows them to intermix.

NREL developed another process that involves three deposition steps and produced the current CIGS efficiency record holder at 20.3%. The first step in NREL's method is codeposition of In, Ga, and Se. This is followed by Cu and Se deposited at a higher temperature to allow for diffusion and intermixing of the elements. In the final stage In, Ga, and Se are again deposited to make the overall composition Cu deficient.[12]

Würth Solar began producing CIGS cells using an inline coevaporation system in 2005 with module efficiencies between 11% and 12%. They opened another production facility and continued to improve efficiency and yield. Other companies scaling up coevaporation processes include Global Solar and Ascent Solar.[34] Global Solar used an inline three stage deposition process. In all of the steps Se is supplied in excess in the vapor phase. In and Ga are first evaporated followed by Cu and then by In and Ga to make the film Cu deficient. These films performed quite favorably in relation to other manufacturers and to absorbers grown at NREL and the Institute for Energy Conversion (IEC).[14] However, modules of Global Solar's films did not perform as well. The property in which the module most obviously under-performed was a low VOC, which is characteristic of high defect density and high recombination velocities. Global Solar's absorber layer outperformed the NREL absorber in carrier lifetime and hall mobility. However, as completed cells the NREL sample performed better. This is evidence of a poor CIGS/CdS interface, possibly due to the lack of an ODC surface layer on the Global Solar film.

Disadvantages include uniformity issues over large areas and the related difficulty of coevaporating elements in an inline system. Also, high growth temperatures raise the thermal budget and costs. Additionally, coevaporation is plagued by low material utilization (deposition on chamber walls instead of the substrate, especially for selenium) and expensive vacuum equipment.[17][36] A way to enhance Se utilisation is via a thermal or plasma-enhanced selenium-cracking process,[38][39] which can be coupled with an ion beam source for ion beam assisted deposition.[40]

Chemical vapor deposition edit

Chemical vapor deposition (CVD) has been implemented in multiple ways for the deposition of CIGS. Processes include atmosphere pressure metal organic CVD (AP-MOCVD), plasma-enhanced CVD (PECVD), low-pressure MOCVD (LP-MOCVD), and aerosol assisted MOCVD (AA-MOCVD). Research is attempting to switch from dual-source precursors to single-source precursors.[12] Multiple source precursors must be homogeneously mixed and the flow rates of the precursors have to be kept at the proper stoichiometry. Single-source precursor methods do not suffer from these drawbacks and should enable better control of film composition.

As of 2014 CVD was not used for commercial CIGS synthesis. CVD produced films have low efficiency and a low VOC, partially a result of a high defect concentration. Additionally, film surfaces are generally quite rough which serves to further decrease the VOC. However, the requisite Cu deficiency has been achieved using AA-MOCVD along with a (112) crystal orientation.

CVD deposition temperatures are lower than those used for other processes such as co-evaporation and selenization of metallic precursors. Therefore, CVD has a lower thermal budget and lower costs. Potential manufacturing problems include difficulties converting CVD to an inline process as well as the expense of handling volatile precursors.

Electrospray deposition edit

CIS films can be produced by electrospray deposition. The technique involves the electric field assisted spraying of ink containing CIS nano-particles onto the substrate directly and then sintering in an inert environment.[41] The main advantage of this technique is that the process takes place at room temperature and it is possible to attach this process with some continuous or mass production system like roll-to-roll production mechanism.[42]

Rear surface passivation edit

Concepts of the rear surface passivation for CIGS solar cells shows the potential to improve the efficiency. The rear passivation concept has been taken from passivation technology of Silicon solar cells.[43] Al2O3 and SiO2 have been used as the passivation materials. Nano-sized point contacts on Al2O3 layer [44] and line contacts on SiO2 layer [45] provide the electrical connection of CIGS absorber to the rear electrode Molybdenum. The point contacts on the Al2O3 layer are created by e-beam lithography and the line contacts on the SiO2 layer are created using photolithography. It is also seen that the implementation of the passivation layers does not change the morphology of the CIGS layers

See also edit

References edit

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External links edit

  • Publications, Presentations, and News Database of the National Renewable Energy Laboratory.
  • World's Largest CIGS Solar Array Operational In Arizona.
  • Michael Kanellos Silicon vs. CIGS: With solar energy, the issue is material October 2, 2006 CNET News.com
  • CIGS to emerge as the major thin-film photovoltaic technology by 2020[permanent dead link]

January 01, 1970
copper, indium, gallium, selenide, solar, cell, copper, indium, gallium, selenide, solar, cell, cigs, cell, sometimes, cell, thin, film, solar, cell, used, convert, sunlight, into, electric, power, manufactured, depositing, thin, layer, copper, indium, gallium. A copper indium gallium selenide solar cell or CIGS cell sometimes CI G S or CIS cell is a thin film solar cell used to convert sunlight into electric power It is manufactured by depositing a thin layer of copper indium gallium selenide solid solution on glass or plastic backing along with electrodes on the front and back to collect current Because the material has a high absorption coefficient and strongly absorbs sunlight a much thinner film is required than of other semiconductor materials CIGS cell on a flexible plastic backing Other architectures use rigid CIGS panels sandwiched between two panes of glass CIGS is one of three mainstream thin film photovoltaic PV technologies the other two being cadmium telluride and amorphous silicon Like these materials CIGS layers are thin enough to be flexible allowing them to be deposited on flexible substrates However as all of these technologies normally use high temperature deposition techniques the best performance normally comes from cells deposited on glass even though advances in low temperature deposition of CIGS cells have erased much of this performance difference CIGS outperforms polysilicon at the cell level however its module efficiency is still lower due to a less mature upscaling 1 Thin film market share is stagnated at around 15 percent leaving the rest of the PV market to conventional solar cells made of crystalline silicon In 2013 the market share of CIGS alone was about 2 percent and all thin film technologies combined fell below 10 percent 2 CIGS cells continue being developed as they promise to reach silicon like efficiencies while maintaining their low costs as is typical for thin film technology 3 Prominent manufacturers of CIGS photovoltaics were the now bankrupt companies Nanosolar and Solyndra Current market leader is the Japanese company Solar Frontier with Global Solar and GSHK Solar also producing solar modules free of any heavy metals such as cadmium and or lead 4 Many CIGS solar panel manufacturer companies have gone bankrupt 5 Contents 1 Properties 2 Structure 2 1 Conversion efficiency 2 2 Comparison 2 2 1 Conventional crystalline silicon 2 2 2 Other thin films 3 Production 3 1 Film production 3 1 1 Selenization 3 1 2 Sputtering of metallic layers followed by selenization 3 1 3 Chalcogenization of particulate precursor layers 3 1 4 Electrodeposition followed by selenization 3 1 5 Precursor combination by wafer bonding inspired technique 3 2 Coevaporation 3 3 Chemical vapor deposition 3 4 Electrospray deposition 4 Rear surface passivation 5 See also 6 References 7 External linksProperties editCIGS is a I III VI2 compound semiconductor material composed of copper indium gallium and selenium The material is a solid solution of copper indium selenide often abbreviated CIS and copper gallium selenide with a chemical formula of CuInxGa 1 x Se2 where the value of x can vary from 1 pure copper indium selenide to 0 pure copper gallium selenide It is a tetrahedrally bonded semiconductor with the chalcopyrite crystal structure The bandgap varies continuously with x from about 1 0 eV for copper indium selenide to about 1 7 eV for copper gallium selenide 6 nbsp Figure 1 Structure of a CIGS device CdS is used optionally and some CIGS cells contain no cadmium at all 7 CIGS has an exceptionally high absorption coefficient of more than 105 cm for 1 5 eV and higher energy photons 8 CIGS solar cells with efficiencies around 20 have been claimed by the National Renewable Energy Laboratory NREL the Swiss Federal Laboratories for Materials Science and Technology Empa and the German Zentrum fur Sonnenenergie und Wasserstoff Forschung ZSW translated Center for Solar Energy and Hydrogen Research which is the record to date for any thin film solar cell 9 10 In 2024 a CIGS efficiency record of 23 64 was claimed 11 All high performance CIGS absorbers in solar cells have similarities independent of production technique First they are polycrystalline a phase which has the chalcopyrite crystal structure shown in Figure 3 The second property is an overall Cu deficiency 12 Cu deficiency increases the majority carrier hole concentration by increasing the number of electron accepting Cu vacancies When CIGS films are In rich Cu deficient the film s surface layer forms an ordered defect compound ODC with a stoichiometry of Cu In Ga 3 Se5 The ODC is n type forming a p n homojunction in the film at the interface between the a phase and the ODC The recombination velocity at the CIGS CdS interface is decreased by the homojunction s presence The drop in interface recombination attributable to ODC formation is demonstrated by experiments which have shown that recombination in the bulk of the film is the main loss mechanism in Cu deficient films while in Cu rich films the main loss is at the CIGS CdS interface 12 13 nbsp Figure 3 CIGS unit cell Red Cu Yellow Se Blue In Ga Sodium incorporation is necessary for optimal performance Ideal Na concentration is considered to be approximately 0 1 Na is commonly supplied by the soda lime glass substrate but in processes that do not use this substrate the Na must be deliberately added Na s beneficial effects include increases in p type conductivity texture and average grain size Furthermore Na incorporation allows for performance to be maintained over larger stoichiometric deviations 8 Simulations have predicted that Na on an In site creates a shallow acceptor level and that Na serves to remove In on Cu defects donors but reasons for these benefits are controversial Na is also credited with catalyzing oxygen absorption Oxygen passivates Se vacancies that act as compensating donors and recombination centers Alloying CIS CuInSe2 with CGS CuGaSe2 increases the bandgap To reach the ideal bandgap for a single junction solar cell 1 5 eV a Ga In Ga ratio of roughly 0 7 is optimal However at ratios above 0 3 device performance drops off Industry currently targets the 0 3 Ga In Ga ratio resulting in bandgaps between 1 1 and 1 2 eV The decreasing performance has been postulated to be a result of CGS not forming the ODC which is necessary for a good interface with CdS 12 The highest efficiency devices show substantial texturing or preferred crystallographic orientation A 204 surface orientation is observed in the best quality devices 8 A smooth absorber surface is preferred to maximize the ratio of the illuminated area to the area of the interface The area of the interface increases with roughness while illuminated area remains constant decreasing open circuit voltage VOC Studies have also linked an increase in defect density to decreased VOC Recombination in CIGS has been suggested to be dominated by non radiative processes Theoretically recombination can be controlled by engineering the film and is extrinsic to the material 14 Structure editThe most common device structure for CIGS solar cells is shown in the diagram see Figure 1 Structure of a CIGS device Soda lime glass of about of 1 3 millimetres thickness is commonly used as a substrate because the glass sheets contains sodium which has been shown to yield a substantial open circuit voltage increase 15 notably through surface and grain boundary defects passivation 16 However many companies are also looking at lighter and more flexible substrates such as polyimide or metal foils 17 A molybdenum Mo metal layer is deposited commonly by sputtering which serves as the back contact and reflects most unabsorbed light back into the CIGS absorber Following molybdenum deposition a p type CIGS absorber layer is grown by one of several unique methods A thin n type buffer layer is added on top of the absorber The buffer is typically cadmium sulfide CdS deposited via chemical bath deposition The buffer is overlaid with a thin intrinsic zinc oxide layer i ZnO which is capped by a thicker aluminium Al doped ZnO layer The i ZnO layer is used to protect the CdS and the absorber layer from sputtering damage while depositing the ZnO Al window layer since the latter is usually deposited by DC sputtering known as a damaging process 18 The Al doped ZnO serves as a transparent conducting oxide to collect and move electrons out of the cell while absorbing as little light as possible The CuInSe2 based materials that are of interest for photovoltaic applications include several elements from groups I III and VI in the periodic table These semiconductors are especially attractive for solar applications because of their high optical absorption coefficients and versatile optical and electrical characteristics which can in principle be manipulated and tuned for a specific need in a given device 19 Conversion efficiency edit nbsp Solar cell efficiencies of various technologies as tracked by NREL with CIGS progress in green CIGS is mainly used in the form of polycrystalline thin films The best efficiency achieved as of September 2014 was 21 7 20 A team at the National Renewable Energy Laboratory achieved 19 9 a record at the time 21 by modifying the CIGS surface and making it look like CIS 22 These examples were deposited on glass which meant the products were not mechanically flexible In 2013 scientists at the Swiss Federal Laboratories for Materials Science and Technology developed CIGS cells on flexible polymer foils with a new record efficiency of 20 4 23 These display both the highest efficiency and greatest flexibility The U S National Renewable Energy Laboratory confirmed 13 8 module efficiency of a large area meter square production panel and 13 total area and 14 2 aperture area efficiency with some production modules 22 In September 2012 the German Manz AG presented a CIGS solar module with an efficiency of 14 6 on total module surface and 15 9 on aperture which was produced on a mass production facility 24 MiaSole obtained a certified 15 7 aperture area efficiency on a 1m2 production module 25 and Solar Frontier claimed a 17 8 efficiency on a 900 cm2 module 26 Higher efficiencies around 30 can be obtained by using optics to concentrate the incident light The use of gallium increases the optical band gap of the CIGS layer as compared to pure CIS thus increasing the open circuit voltage 22 27 Gallium s relative abundance compared to indium lowers costs Lab record CIGS efficiencies by substrate a Substrate Glass Steel Aluminium Polymer Efficiency 22 9 17 7 16 2 20 4 Institute Solar Frontier b Empa Empa Empa Source Swissolar Flisom presentation November 2014 28 Note a lab cell with 0 5 cm2 b http www solar frontier com eng news 2017 1220 press html Comparison edit Conventional crystalline silicon edit Unlike conventional crystalline silicon cells based on a homojunction the structure of CIGS cells is a more complex heterojunction system A direct bandgap material CIGS has very strong light absorption and a layer of only 1 2 micrometers mm is enough to absorb most of the sunlight By comparison a much greater thickness of about 160 190 mm is required for crystalline silicon The active CIGS layer can be deposited in a polycrystalline form directly onto molybdenum Mo coated on a variety of several different substrates such as glass sheets steel bands and plastic foils made of polyimide This uses less energy than smelting large amounts of quartz sand in electric furnaces and growing large crystals necessary for conventional silicon cells and thus reduces its energy payback time significantly Also unlike crystalline silicon these substrates can be flexible 29 In the highly competitive PV industry pressure increased on CIGS manufacturers leading to the bankruptcy of several companies as prices for conventional silicon cells declined rapidly in recent years However CIGS solar cells have become as efficient as multicrystalline silicon cells the most common type of solar cells CIGS and CdTe PV remain the only two commercially successful thin film technologies in a globally fast growing PV market Other thin films edit In photovoltaics thinness generally is in reference to so called first generation high efficiency silicon cells which are manufactured from bulk wafers hundreds of micrometers thick 30 Thin films sacrifice some light gathering efficiency but use less material 31 In CIGS the efficiency tradeoff is less severe than in silicon The record efficiencies for thin film CIGS cells are slightly lower than that of CIGS for lab scale top performance cells In 2008 CIGS efficiency was by far the highest compared with those achieved by other thin film technologies such as cadmium telluride photovoltaics CdTe or amorphous silicon a Si 21 CIS and CGS solar cells offer total area efficiencies of 15 0 and 9 5 32 respectively In 2015 the gap with the other thin film technologies has been closed with record cell efficiencies in laboratories of 21 5 for CdTe FirstSolar and 21 7 for CIGS ZSW See also NREL best research cell efficiency chart 33 Production editFilm production edit The most common vacuum based process is to co evaporate or co sputter copper gallium and indium onto a substrate at room temperature then anneal the resulting film with a selenide vapor An alternative process is to co evaporate copper gallium indium and selenium onto a heated substrate A non vacuum based alternative process deposits nanoparticles of the precursor materials on the substrate and then sinters them in situ Electroplating is another low cost alternative to apply the CIGS layer The following sections outline the various techniques for precursor deposition processing including sputtering of metallic layers at low temperatures printing of inks containing nanoparticles electrodeposition and a technique inspired by wafer bonding Selenization edit The Se supply and selenization environment is important in determining the properties and quality of the film When Se is supplied in the gas phase for example as H2Se or elemental Se at high temperatures the Se becomes incorporated into the film by absorption and subsequent diffusion During this step called chalcogenization complex interactions occur to form a chalcogenide These interactions include formation of Cu In Ga intermetallic alloys formation of intermediate metal selenide binary compounds and phase separation of various stoichiometric CIGS compounds Because of the variety and complexity of the reactions the properties of the CIGS film are difficult to control 8 The Se source affects the resulting film properties H2Se offers the fastest Se incorporation into the absorber 50 at Se can be achieved in CIGS films at temperatures as low as 400 C By comparison elemental Se only achieves full incorporation with reaction temperatures above 500 C Films formed at lower temperatures from elemental Se were Se deficient but had multiple phases including metal selenides and various alloys Use of H2Se provides the best compositional uniformity and the largest grain sizes However H2Se is highly toxic and is classified as an environmental hazard Sputtering of metallic layers followed by selenization edit In this method a metal film of Cu In and Ga is sputtered at or near room temperature and reacted in a Se atmosphere at high temperature This process has higher throughput than coevaporation and compositional uniformity can be more easily achieved Sputtering a stacked multilayer of metal for example a Cu In Ga Cu In Ga structure produces a smoother surface and better crystallinity in the absorber compared to a simple bilayer Cu Ga alloy In or trilayer Cu In Ga sputtering These attributes result in higher efficiency devices but forming the multilayer is a more complicated deposition process and did not merit the extra equipment or the added process complexity 12 Additionally the reaction rates of Cu Ga and Cu In layers with Se are different If the reaction temperature is not high enough or not held long enough CIS and CGS form as separate phases Companies currently that used similar processes include Showa Shell Avancis Miasole Honda Soltec and Energy Photovoltaics EPV 34 Showa Shell sputtered a Cu Ga alloy layer and an In layer followed by selenization in H2Se and sulfurization in H2S The sulfurization step appears to passivate the surface in a way similar to CdS in most other cells Thus the buffer layer used is Cd free eliminating any environmental impact of Cd Showa Shell reported a maximum module efficiency of 13 6 with an average of 11 3 for 3600 cm2 substrates 17 Shell Solar uses the same technique as Showa Shell to create the absorber however their CdS layer comes from chemical vapor deposition Modules sold by Shell Solar claim 9 4 module efficiency Miasole had procured venture capital funds for its process and scale up A record 17 4 aperture efficiency module was confirmed by Fraunhofer in 2019 35 EPV uses a hybrid between coevaporation and sputtering in which In and Ga are evaporated in a Se atmosphere This is followed by Cu sputtering and selenization Finally In and Ga are again evaporated in the presence of Se Based on Hall measurements these films have a low carrier concentration and relatively high mobility EPV films have a low defect concentration Chalcogenization of particulate precursor layers edit In this method metal or metal oxide nanoparticles are used as the precursors for CIGS growth These nanoparticles are generally suspended in a water based solution and then applied to large areas by various methods such as printing The film is then dehydrated and if the precursors are metal oxides reduced in a H2 N2 atmosphere Following dehydration the remaining porous film is sintered and selenized at temperatures greater than 400 C 12 14 36 Nanosolar and International Solar Electric Technology ISET unsuccessfully attempted to scale up this process 17 ISET uses oxide particles while Nanosolar did not discuss its ink The advantages of this process include uniformity over large areas non vacuum or low vacuum equipment and adaptability to roll to roll manufacturing When compared to laminar metal precursor layers sintered nanoparticles selenize more rapidly The increased rate is a result of the greater surface area associated with porosity Porosity produces rougher absorber surfaces Use of particulate precursors allows for printing on a large variety of substrates with materials utilization of 90 or more Little research and development supported this technique Nanosolar reported a cell not module efficiency of 14 however this was not verified by any national laboratory testing nor did they allow onsite inspections In independent testing 14 ISET s absorber had the 2nd lowest efficiency at 8 6 However all the modules that beat ISET s module were coevaporated a process which has manufacturing disadvantages and higher costs ISET s sample suffered most from low VOC and low fill factor indicative of a rough surface and or a high number of defects aiding recombination Related to these issues the film had poor transport properties including a low Hall mobility and short carrier lifetime Electrodeposition followed by selenization edit Precursors can be deposited by electrodeposition Two methodologies exist deposition of elemental layered structures and simultaneous deposition of all elements including Se Both methods require thermal treatment in a Se atmosphere to make device quality films Because electrodeposition requires conductive electrodes metal foils are a logical substrate Electrodeposition of elemental layers is similar to the sputtering of elemental layers Simultaneous deposition employs a working electrode cathode a counter electrode anode and a reference electrode as in Figure 4 A metal foil substrate is used as the working electrode in industrial processes An inert material provides the counter electrode and the reference electrode measures and controls the potential The reference electrode allows the process to be performed potentiostatically allowing control of the substrate s potential 12 nbsp Figure 4 CIGS electrodeposition apparatus Simultaneous electrodeposition must overcome the fact that the elements standard reduction potentials are not equal causing preferential deposition of a single element This problem is commonly alleviated by adding countering ions into solution for each ion to be deposited Cu2 Se4 In3 and Ga3 thus changing that ion s reduction potential Further the Cu Se system has a complicated behavior and the film s composition depends on the Se4 Cu2 ion flux ratio which can vary over the film surface This requires the precursor concentrations and deposition potential to be optimized Even with optimization reproducibility is low over large areas due to composition variations and potential drops along the substrate The resulting films have small grains are Cu rich and generally contain Cu2 xSex phases along with impurities from the solution Annealing is required to improve crystallinity For efficiencies higher than 7 a stoichiometry correction are required The correction was originally done via high temperature physical vapor deposition which is not practical in industry Solopower is currently producing cells with gt 13 7 conversion efficiency as per NREL 37 Precursor combination by wafer bonding inspired technique edit nbsp Figure 5 Schematic of wafer bonding inspired technique In this process two different precursor films are deposited separately on a substrate and a superstrate The films are pressed together and heated to release the film from the reusable superstrate leaving a CIGS absorber on the substrate Figure 5 Heliovolt patented this procedure and named it the FASST process In principle the precursors can be deposited at low temperature using low cost deposition techniques lowering module cost However the first generations of products use higher temperature PVD methods and do not achieve full cost cutting potential Flexible substrates could eventually be used in this process Typical film characteristics are not known outside of the company as no research has been conducted by independently funded laboratories However Heliovolt claimed a top cell efficiency of 12 2 Coevaporation edit Coevaporation or codeposition is the most prevalent CIGS fabrication technique Boeing s coevaporation process deposits bilayers of CIGS with different stoichiometries onto a heated substrate and allows them to intermix NREL developed another process that involves three deposition steps and produced the current CIGS efficiency record holder at 20 3 The first step in NREL s method is codeposition of In Ga and Se This is followed by Cu and Se deposited at a higher temperature to allow for diffusion and intermixing of the elements In the final stage In Ga and Se are again deposited to make the overall composition Cu deficient 12 Wurth Solar began producing CIGS cells using an inline coevaporation system in 2005 with module efficiencies between 11 and 12 They opened another production facility and continued to improve efficiency and yield Other companies scaling up coevaporation processes include Global Solar and Ascent Solar 34 Global Solar used an inline three stage deposition process In all of the steps Se is supplied in excess in the vapor phase In and Ga are first evaporated followed by Cu and then by In and Ga to make the film Cu deficient These films performed quite favorably in relation to other manufacturers and to absorbers grown at NREL and the Institute for Energy Conversion IEC 14 However modules of Global Solar s films did not perform as well The property in which the module most obviously under performed was a low VOC which is characteristic of high defect density and high recombination velocities Global Solar s absorber layer outperformed the NREL absorber in carrier lifetime and hall mobility However as completed cells the NREL sample performed better This is evidence of a poor CIGS CdS interface possibly due to the lack of an ODC surface layer on the Global Solar film Disadvantages include uniformity issues over large areas and the related difficulty of coevaporating elements in an inline system Also high growth temperatures raise the thermal budget and costs Additionally coevaporation is plagued by low material utilization deposition on chamber walls instead of the substrate especially for selenium and expensive vacuum equipment 17 36 A way to enhance Se utilisation is via a thermal or plasma enhanced selenium cracking process 38 39 which can be coupled with an ion beam source for ion beam assisted deposition 40 Chemical vapor deposition edit Chemical vapor deposition CVD has been implemented in multiple ways for the deposition of CIGS Processes include atmosphere pressure metal organic CVD AP MOCVD plasma enhanced CVD PECVD low pressure MOCVD LP MOCVD and aerosol assisted MOCVD AA MOCVD Research is attempting to switch from dual source precursors to single source precursors 12 Multiple source precursors must be homogeneously mixed and the flow rates of the precursors have to be kept at the proper stoichiometry Single source precursor methods do not suffer from these drawbacks and should enable better control of film composition As of 2014 CVD was not used for commercial CIGS synthesis CVD produced films have low efficiency and a low VOC partially a result of a high defect concentration Additionally film surfaces are generally quite rough which serves to further decrease the VOC However the requisite Cu deficiency has been achieved using AA MOCVD along with a 112 crystal orientation CVD deposition temperatures are lower than those used for other processes such as co evaporation and selenization of metallic precursors Therefore CVD has a lower thermal budget and lower costs Potential manufacturing problems include difficulties converting CVD to an inline process as well as the expense of handling volatile precursors Electrospray deposition edit CIS films can be produced by electrospray deposition The technique involves the electric field assisted spraying of ink containing CIS nano particles onto the substrate directly and then sintering in an inert environment 41 The main advantage of this technique is that the process takes place at room temperature and it is possible to attach this process with some continuous or mass production system like roll to roll production mechanism 42 Rear surface passivation editConcepts of the rear surface passivation for CIGS solar cells shows the potential to improve the efficiency The rear passivation concept has been taken from passivation technology of Silicon solar cells 43 Al2O3 and SiO2 have been used as the passivation materials Nano sized point contacts on Al2O3 layer 44 and line contacts on SiO2 layer 45 provide the electrical connection of CIGS absorber to the rear electrode Molybdenum The point contacts on the Al2O3 layer are created by e beam lithography and the line contacts on the SiO2 layer are created using photolithography It is also seen that the implementation of the passivation layers does not change the morphology of the CIGS layersSee also edit nbsp Renewable energy portal nbsp Energy portal List of CIGS companies CZTSReferences edit Green Martin A et al Solar cell efficiency tables version 50 Progress in Photovoltaics Research and Applications 25 7 2017 668 676 Photovoltaics Report Fraunhofer ISE July 28 2014 pages 18 19 PDF Andorka Frank 2014 01 08 CIGS Solar Cells Simplified www solarpowerworldonline com Solar Power World Archived from the original on 19 August 2014 Retrieved 16 August 2014 CIS Ecology Solar Frontier Retrieved 8 July 2015 TSMC Shutting Down Its CIGS Thin Film Solar Manufacturing www greentechmedia com Tinoco T Rincon C Quintero M Perez G Sanchez 1991 Phase Diagram and Optical Energy Gaps for CuInyGa1 ySe2 Alloys Physica Status Solidi A 124 2 427 Bibcode 1991PSSAR 124 427T doi 10 1002 pssa 2211240206 Solar Frontier com CIS Advantages Archived 2014 11 03 at the Wayback Machine a b c d Stanbery B J 2002 Copper Indium Selenides and Related Materials for Photovoltaic Devices Critical Reviews in Solid State and Materials Science 27 2 73 Bibcode 2002CRSSM 27 73S doi 10 1080 20014091104215 S2CID 55612537 Repins I Contreras Miguel A Egaas Brian Dehart Clay Scharf John Perkins Craig L To Bobby Noufi Rommel 2008 19 9 efficient ZnO CdS CuInGaSe2 solar cell with 81 2 fill factor Progress in Photovoltaics Research and Applications 16 3 235 doi 10 1002 pip 822 S2CID 97047370 ZSW Press Releases Zsw bw de Retrieved on 2011 09 13 New world record for CIGS solar cells ScienceDaily Retrieved 2024 02 29 a b c d e f g h Kemell Marianna Ritala Mikko Leskela Markku 2005 Thin Film Deposition Methods for CuInSe2 Solar Cells Critical Reviews in Solid State and Materials Sciences 30 1 1 Bibcode 2005CRSSM 30 1K doi 10 1080 10408430590918341 S2CID 55705282 Ihlal A Bouabid K Soubane D Nya M Aittalebali O Amira Y Outzourhit A Nouet G 2007 Comparative study of sputtered and electrodeposited CI S Se and CIGSe thin films Thin Solid Films 515 15 5852 Bibcode 2007TSF 515 5852I doi 10 1016 j tsf 2006 12 136 a b c d Repins I L Stanbery B J Young D L Li S S Metzger W K Perkins C L Shafarman W N Beck M E Chen L Kapur V K Tarrant D Gonzalez M D Jensen D G Anderson T J Wang X Kerr L L Keyes B Asher S Delahoy A von Roedern B 2006 Comparison of device performance and measured transport parameters in widely varying Cu In Ga Se S solar cells Progress in Photovoltaics Research and Applications 14 25 doi 10 1002 pip 654 S2CID 6395345 Hedstrom J Ohlsen H Bodegard M Kylner A Stolt L Hariskos D Ruckh M Schock H W 1993 ZnO CDS Cu In Ga Se Sub 2 Thin film solar cells with improved performance Conference Record of the Twenty Third IEEE Photovoltaic Specialists Conference 1993 Cat No 93CH3283 9 pp 364 371 doi 10 1109 PVSC 1993 347154 ISBN 978 0 7803 1220 3 S2CID 119887948 Kronik L Cahen D Schock H W 1998 Effects of sodium on polycrystalline Cu In Ga Se2 and its solar cell performance Advanced Materials 10 31 36 doi 10 1002 SICI 1521 4095 199801 10 1 lt 31 AID ADMA31 gt 3 0 CO 2 3 a b c d Dhere Neelkanth G 2007 Toward GW year of CIGS production within the next decade Solar Energy Materials and Solar Cells 91 15 16 1376 doi 10 1016 j solmat 2007 04 003 Cooray NF Kushiya K Fujimaki A Sugiyama I Miura T Okumura D Sato M Ooshita M Yamase O 1997 Large area ZnO films optimized for graded band gap Cu InGa Se2 based thin film mini modules Solar Energy Materials and Solar Cells 49 1 4 291 297 doi 10 1016 S0927 0248 97 00055 X Thin film CuInSe2 Cd Zn S Heterojunction Solar Cell Characterization and Modeling Murat Nezir Eron PhD Thesis Drexel University 1984 Philadelphia ZSW ZSW Brings World Record Back to Stuttgart Archived from the original on 2015 04 24 Retrieved 2015 06 03 a b Characterization of 19 9 Efficient CIGS Absorbers PDF National Renewable Energy Laboratory May 2008 Retrieved 10 February 2011 a b c The status and future of the photovoltaics industry PDF David E Carlson Chief Scientist BP Solar 14 March 2010 Retrieved 10 February 2011 Empa takes thin film solar cells to a new level A new world record for solar cell efficiency Empa 18 January 2013 Retrieved 8 July 2015 Top 10 World s Most Efficient CI G S Modules Archived 2013 01 24 at the Wayback Machine Solarplaza com Retrieved on 2013 02 18 Miasole MiaSole Achieves 15 7 Efficiency with Commercial Scale CIGS Thin Film Solar Modules PDF Retrieved 30 November 2012 Solar Frontier Solar Frontier Sets New Efficiency World Record Retrieved 30 November 2012 Solar cell efficiency tables Ver 33 PDF National Institute of Advanced Industrial Science and Technology AIST Retrieved 10 February 2011 Flisom Flexible PV from Lab to Fab PDF Flisom AG 4 November 2014 p 4 First sales for world s cheapest solar cells Chemistry world February 2008 Retrieved 6 April 2011 US 20090223551 patent Nurul Amziah Md Yunus Nik Hasniza Nik Aman Nima Khoshsirat 2015 Comparison between thin film solar cells and copper indium gallium diselenide in Southeast Asia IET Renewable Power Generation 9 8 1079 1086 Bibcode 2015IRPG 9 1079M doi 10 1049 iet rpg 2015 0114 S2CID 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Cells 93 6 7 792 doi 10 1016 j solmat 2008 09 043 Kawamura M Fujita Toshiyuki Yamada Akira Konagai Makoto 2009 CIGS thin film solar cells grown with cracked selenium Journal of Crystal Growth 311 3 753 Bibcode 2009JCrGr 311 753K doi 10 1016 j jcrysgro 2008 09 091 Solarion AG 2009 10 07 World record 13 4 conversion efficiency in solar cells on plastic film Archived 2012 03 05 at the Wayback Machine press release Muhammad Nauman Malik Sundharam Sridharan Dang Hyun Woo Lee Ayoung Ryu Beyoung Hwan Choi Kyung Hyun 2011 CIS layer deposition through electrospray process for solar cell fabrication Current Applied Physics 11 1 S68 Bibcode 2011CAP 11S 68M doi 10 1016 j cap 2010 11 059 Choi Kyung Hyun Muhammad Nauman Malik Dang Hyun Woo Lee Ayoung Hwang Jin Soo Nam Jong Won Ryu Beyoung Hwan 2011 Electrospray deposition of thin copper indium diselenide films International Journal of Materials Research 102 10 1252 Bibcode 2011IJMR 102 1252C doi 10 3139 146 110581 S2CID 137436772 Vermang Bart Watjen Jorn Timo Fjallstrom Viktor Rostvall Fredrik Edoff Marika Kotipalli Ratan Henry Frederic Flandre Denis 2014 Employing Si solar cell technology to increase efficiency of ultra thin Cu In Ga Se2 solar cells Progress in Photovoltaics Research and Applications 22 10 1023 1029 doi 10 1002 pip 2527 PMC 4540152 PMID 26300619 Bose S Cunha J M V Borme J Chen W C Nilsson N S Teixeira J P Gaspar J Leitao J P Edoff M Fernandes P A Salome P M P 2019 A morphological and electronic study of ultrathin rear passivated Cu In Ga Se2 solar cells Thin Solid Films 671 77 84 Bibcode 2019TSF 671 77B doi 10 1016 j tsf 2018 12 028 hdl 10773 30445 S2CID 139582764 Bose Sourav Cunha Jose M V Suresh Sunil De Wild Jessica Lopes Tomas S Barbosa Joao R S Silva Ricardo Borme Jerome Fernandes Paulo A Vermang Bart Salome Pedro M P 2018 Optical Lithography Patterning of SiO2 Layers for Interface Passivation of Thin Film Solar Cells RRL Solar 2 12 1800212 doi 10 1002 solr 201800212 hdl 10773 30564 S2CID 139388117 External links editCopper Indium Diselenide Publications Presentations and News Database of the National Renewable Energy Laboratory World s Largest CIGS Solar Array Operational In Arizona Michael Kanellos Silicon vs CIGS With solar energy the issue is material October 2 2006 CNET News com CIGS to emerge as the major thin film photovoltaic technology by 2020 permanent dead link Retrieved from https en wikipedia org w index php title Copper indium gallium selenide solar cell amp oldid 1223156599, wikipedia, wiki, book, books, library,

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