Special Report                                                                   Special Report


 OPVs are currently only about half   Table 2: Chemicals and gases used in electronics manufacturing  solar cells has signifi cantly improved,
 as  effi cient  as  crystalline  silicon  cells   Category  Products      with lab-scale cells now exceeding
 and have shorter operating lifetimes,   Bulk gases  Nitrogen, oxygen, argon, helium, and hydrogen;  effi ciencies of 26%, up from about 20%
 but could be less expensive to manu-                                     a decade ago.
 facture in high volumes. They can also   Dopants gases  Arsine, phosphine, boron trichloride, boron tri-
 be applied to a variety of  supporting   fl uoride, and diborane;            The  record  lab  cell  effi ciency  is
 materials, such as fl exible plastic, mak-  Etchant gases  Boron trichloride, chlorine, chlorine trifl uoride,   27.3% for mono-crystalline and 24.4%
 ing OPV able to serve a wide variety   hydrogen  chloride,  hydrogen  fl uoride,  nitrogen   for multi-crystalline silicon wafer-
 of uses.                       trifl uoride,  silicon  tetrafl uoride,  sulfur  hexa-  based technology.  The  highest  lab
                                fl uoride,  tetra-fl uoromethane,  trifl uoromethane,   effi ciency in TFT is 23.4% for CIGS and
 Other chemical usage           difluoromethane, fluoromethane, hexafluoro-  21.0% for Cd-Te solar cells. Record lab
 Other chemicals used in PVs    ethane,  pentafl uoroethane,  octafl uoropropane,   cell effi ciency for Perovskite is 25.2%.
 include:                       and octafl uorocyclobutane;
    Conductive  inks, based on silver   Chemical vapour deposition  Silane, dichlorosilane, trichlorosilane, silicon tetra-  In the last 10 years, the effi ciency
 Fig. 3: Market share of Thin Film Technologies by type.  and copper, which are used for   (CVD) chemicals  chloride, disilane, tetraethylorthosilicate, silicon   of commercial mono-crystalline wafer-
 Source: Reference 2.
 making the electrical contacts that   tetrafl uoride,  methylsilane,  germane,  ammonia,   based silicon  modules increased  from
 of materials that are printed, coated, or  methylammonium lead iodide. Solvents,   collect and transport the generated   nitrous oxide, and tungsten hexafl uoride; and  about  16% to  22% and  more. At the
 vacuum-deposited  onto an underlying  such as dimethylformamide and   electricity;  Other wet chemicals  Acetic acid, acetone, ammonium fluoride,   same  time,  the  effi ciency  of  Cd-Te
 support layer (substrate). They are typi-  dimethyl sulphoxide are critical in the   Encapsulants, of which ethylene-  ammonium hydroxide, hydrochloric acid, hydro  module increased from 9% to nearly

 cally easy to assemble and can reach  formation of the perovskite layer dur-  vinyl acetate  (EVA) copolymer is   fl uoric acid, hydrogen peroxide, isopropyl alcohol,   20%.
 effi ciencies  similar  to  crystalline  silicon.  ing the fabrication process.  most  commonly used, to  protect   nitric acid, phosphoric acid, and sulfuric acid.
 In  the  lab,  perovskite  solar  cell  effi -  the PV cells from moisture and   In the laboratory, the best perform-
 ciencies have improved faster than any  Organic photovoltaics  mechanical damage; and   Table 3: Chemicals used in crystalline silicon technology  ing modules are based on mono-crys-
 other PV material, from 3% in 2009 to   Organic PVs (OPVs) are  made   Back-sheet materials that includes   Type  Materials & chemicals  talline  silicon  with  24.9%  effi ciency.

 over 25% in 2020. To be commercially  from conjugated polymers (e.g., poly  polyvinylidene  fl uoride  (PVDF),   Basic materials  Monocrystalline silicon, polycrystalline silicon.  Record  effi ciencies  demonstrate  the
 viable, perovskite PV cells have to  (3-hexylthiophene) (P3HT)), which are   used to protect the back of solar   Speciality gases  Ammonia, argon, fl uorine, nitrogen trifl uoride, nitrous oxide.  potential  for  further  effi ciency  increases
 become stable enough to survive 20 years  used as the active layer in OPV cells.   panels.  Bulk gases  Hydrogen, nitrogen, oxygen.  at the production level.
 outdoors, so researchers are working on  Fullerenes (e.g., PCBM, ([6,6]-phenyl-C -
 61
 making them more  durable and  deve-  butyric acid methyl ester)) are often   Chemicals are also used in the qua-  Silicon precursor   Dichlorosilane, silane, silicon tetrachloride, trichlorosilane.  Perovskite solar cells have been a
 loping large-scale, low-cost manufac-  used as electron acceptors in OPV cells,  lity control and testing stages of PV manu-  gases  major breakthrough in the last decade,
 turing techniques.  and  alternatives  such  as diketopyrro-  facturing. Solutions and reagents are   Dopants  Boron tribromide, phosphorus oxychloride.  and rapidly advanced in terms of effi -
 lopyrrole (DPP) and non-fullerene  employed to test  for impurities,  check   Wet chemicals  Acetic acid, ammonium hydroxide, ethanol, ethylene,   ciencies from around 10% to over 25%.
 Perovskite solar cells commonly  acceptors have gained popularity in  electrical characteristics, and  ensure   hydrochloric acid, hydrofl uoric acid, hydrogen peroxide,   They  are also being  integrated into
 use lead halide perovskites, such  recent years.  solar cells meet performance standards.   isopropyl alcohol, nitric acid, phosphoric acid, polyethy-  tandem cells with silicon, pushing the
                        lene glycol, potassium hydroxide, sodium hydroxide,   combined effi ciencies beyond 30%.
                        sulphuric acid, tertrafl uoroethylene.
        Metallisation   Front side n-type (silver); back side p-type aluminium.  For concentrated PVs (CPVs),
        Encapsulants    Ethylene vinyl acetate.                           multi-junction cells have reached
                                                                          effi ciencies  of  over  40%  in  lab  settings,
       After manufacturing, PV modules are  rials like silicon, silver, and rare metals,  benefi ting  from  advances  in  material
       installed in various applications, ranging  and the safe disposal of hazardous sub-  science and fabrication techniques.
       from residential rooftops to large-scale  stances. The development of chemical  CPVs  works with lenses that concen-
       solar farms. The chemical industry’s in-  processes to recycle and repurpose PV  trate the sunlight onto a relatively small
       volvement extends to providing materials  materials is  crucial for  sustainability  area. This happens in combination with
       like sealants, adhesives, and coatings that  and reducing the environmental impact  primary and secondary lenses.  These
       protect the installations from environmen-  of solar energy.       are used directly on the solar cell, which
       tal degradation, UV exposure, and mecha-                           turns the sunlight into electrical energy.
       nical stress. As PV systems reach the end of  PV innovations – focus areas  The primary lenses that are connected
       their operational life, the chemical industry                      in front of the solar cells focus the light
       contributes to the recycling process. This  Effi ciency improvements  and channel it through secondary lenses
 Fig. 4: Materials used in a typical silicon PV cell.  includes the recovery of valuable mate-  The  effi ciency  of  silicon-based  that are attached directly to the cell.

 182  Chemical Weekly  October 22, 2024  Chemical Weekly  October 22, 2024                             183


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