a1983f78-9df3-4a83-bd9b-4eb42e44223fTransistor power THT/SMD SOT93/TO218 3 leads (4.70g) 15.5x12.9x4.7front-end and back-end processing of the wafer, including Czochralski method of silicon growingproduction mix, at plant(4.70g) 15.5x12.9x4.7Integrated circuit, semiconductor chip, processor, chip, microcomputer, logic chip, silicon chipSystemsElectrics and electronicsThe data set covers all relevant process steps and technologies over the supply chain of the represented cradle to gate inventory with a good overall data quality. The inventory is based mainly on industry data and is completed, where necessary, by secondary data. The IC manufacturing process is representative of a combination of IC manufacturing platforms and does not specifically represent any one company or process technology platform.0The data set represents the country specific situation in India, focusing on the main technologies, the region specific characteristics and / or import statistics.The component name contains following information: name of the component, e.g. IC; housing type, e.g. BGA (ball grid array); number of pins, e.g.144 mass of the component in brackets, e.g. (466mg); size details (3 types): 13x13x1.75 - the size is given in mm for length x width x height; D14x25 - the size is given in mm for diameter x height ; 0201 - the size is given in inch (0.02 x 0.01inch) for width and length.
The data sets for ICs (all housing and packaging types), transistors and diodes are based on a parametric model. This model allows individual quantification of the following main modules reflecting mono-crystalline silicon based semiconductor:
- die manufacture
- bond wires
- leadframe
- housing
The module "die manufacture":
The module „die manufacture“ (aka, front-end wafer processing) produces the dominant environmental effect. Scaling of this module is based on die size (which determines the area required in wafer manufacture), the IC technology type and generation or „node“ which determines the technology used in wafer manufacture (the device type: logic, memory, single/power transistor, diode or LED as well as the technology generation or node, which determines the sophistication or complexity of the device), or alternately the number of masks (which can be used to infer the production complexity). The level of integration corresponds to the number of pins in the following way: For a given die area or device size, the more masks necessary for front-end processing, the more pins are required for connection to the chip. The technology node reflects the level of integration of the chip and is used, along with industry standards and reference products, to determine the packaging type required for the IC (or vice versa: the IC device type and generation suggested by the package type).
The model of bare wafer manufacture (to reflect the environmental effects for bare dice) consists of following processes: manufacturing of mono-crystalline silicon (Czochralski method) and wafer manufacturing (including wafer structuring/design). Mono-crystalline silicon manufactured during the Czochralski method are cut into thin silicon wafers and polished to a very high flatness to be used for wafer structuring. The mass of silicon is scaled according to the mass input of silicon material.
The structuring processes (front end) consist of hundreds of steps and many chemical inputs. Scaling of all resources, chemical inputs and emissions takes place according to the process inventory applied for the semiconductor device. The device process inventory can be described by the technology node, or by the number of masks. The table 1 under section „pictogramme“ shows the number of masks related to each type of semiconductor.
Since the last release of the Electronics database, wafer processing has been updated to include newer process technologies which correspond to higher mask counts, as well as new device types (flash memory and DRAM). The MPU process technology reflects a device at the 130 nm CMOS generation with both logic and on-chip memory which is representative of a generic microprocessor unit. The table 2 under section „pictogramme“ shows the number of front-end masks used for each process technology.
The module "bond wires": Gold or aluminium is taken according to material declaration and a wire process is applied.
The module "leadframe": Materials for possible alloys are lead, nickel, copper, aluminium, steel, cobalt and zinc. The respective composition is in accordance with the given material declaration. Each alloy has applied an average sheet making process and a surface coating process. As coating tin, silver or palladium is applicable according to material declaration. The finished leadframe has applied an average bending and punching process.
The module "housing": Materials for possible compositions of housings are epoxy resin, glass fibres, tetra bromo bisphenole-A (TBBA) and antimony trioxide. The respective composition is in accordance with the material declaration for each package type.
Diodes such as MELF or mini MELF have additionally taken into consideration the materials glass, as float glass, and ceramic, based on wet cast manufacture.
LEDs are also based on the parametric IC model. This refers to an estimation that the gallium, arsenic, selenic or other mono-crystalline semiconductor materials may be estimated by the mono-crystalline silicon model since the processing steps are nearly identical from an environmental stand-point. The plastic cap of the THT LED is estimated as epoxy resin because of the provided boundaries of the model.
In addition to the standard modules, the parametric model of SMD-type LEDs contains the following modules:
- Substrate consisting of ceramics (film cast) and is contained in all datasets
- Reflector consisting of aluminum foil
- Lens consisting of silicone
Background system:
Electricity: Electricity is modelled according to the individual country-specific situations. The country-specific modelling is achieved on multiple levels. Firstly, individual energy carrier specific power plants and plants for renewable energy sources are modelled according to the current national electricity grid mix. Modelling the electricity consumption mix includes transmission / distribution losses and the own use by energy producers (own consumption of power plants and "other" own consumption e.g. due to pumped storage hydro power etc.), as well as imported electricity. Secondly, the national emission and efficiency standards of the power plants are modelled as well as the share of electricity plants and combined heat and power plants (CHP). Thirdly, the country-specific energy carrier supply (share of imports and / or domestic supply) including the country-specific energy carrier properties (e.g. element and energy content) are accounted for. Fourthly, the exploration, mining/production, processing and transport processes of the energy carrier supply chains are modelled according to the specific situation of each electricity producing country. The different production and processing techniques (emissions and efficiencies) in the different energy producing countries are considered, e.g. different crude oil production technologies or different flaring rates at the oil platforms.
Thermal energy, process steam: The thermal energy and process steam supply is modelled according to the individual country-specific situation with regard to emission standards and considered energy carriers. The thermal energy and process steam are produced at heat plants. Efficiencies for thermal energy production are by definition 100% in relation to the corresponding energy carrier input. For process steam the efficiency ranges from 85%, 90% to 95%. The energy carriers used for the generation of thermal energy and process steam are modelled according to the specific import situation (see electricity above).
Transports: All relevant and known transport processes are included. Ocean-going and inland ship transport as well as rail, truck and pipeline transport of bulk commodities are considered.
Energy carriers: The energy carriers are modelled according to the specific supply situation (see electricity above).
Refinery products: Diesel fuel, gasoline, technical gases, fuel oils, lubricants and residues such as bitumen are modelled with a parameterised country-specific refinery model. The refinery model represents the current national standard in refining techniques (e.g. emission level, internal energy consumption, etc.) as well as the individual country-specific product output spectrum, which can be quite different from country to country. The supply of crude oil is modelled, again, according to the country-specific situation with the respective properties of the resources.Printed Wiring Board 4-layer rigid FR4 with chemSn elecAuNi finish (Subtractive method)Printed Wiring Board 2-layer rigid FR4 with chem-elec AuNi finish (Subtractive method)Solder paste SnAg3.5Gold (primary)Palladium mixSilver mixElectricity grid mixThe purpose of these products (integrated circuits, diodes, transistors and LEDs) is to control electric signals in electronic products. Integrated circuits, diodes and transistors can calculate and store data, or transmit signals for communication or control. LEDs emit light.electronics_ic_table_diodes.jpgelectronics_ic_table_ics.jpgelectronics_ic_table_transistors.jpgelectronics_ic_table_transistors_continue.jpgelectronics_ics_leds_table 1_package types with typical corresponding process technologies.jpgelectronics_ics_leds_table_2_number of front-end masks used for each process technology.jpgelectronics_glo_general_flow_diagram_ics.jpgAll environmentally-relevant mass inputs and emissions are included, where LCI data (for inputs) or characterization factors (for emissions) are available, but where a representative or proxy LCI data, or impact factor, is not available, the mass input is excluded. Where LCI data is not available for semiconductor grade (99.9998-99.99998%) chemicals, non-highly-pure (industrial grade) chemicals of 99-99.9% purity are used. Where an emissions factor for an exact chemical emission is not available, a representative group impact factor (e.g. NMVOC) is used.LCI resultAttributionalNoneAllocation - market valueAllocation - net calorific valueAllocation - exergetic contentAllocation - massNot applicableForeground system: For the foreground system, no allocation was applied.
Background system: For the combined heat and power production, allocation by exergetic content is applied. For the electricity generation and by-products, e.g. gypsum, allocation by market value is applied due to no common physical properties. Within the refinery allocation by net calorific value and mass is used. For the combined crude oil, natural gas and natural gas liquids production allocation by net calorific value is applied.
For details please see the document "GaBi Databases Modelling Principles"Direct land use change: GHG emissions from direct LUC allocated to good/service for 20 years after the LUC occurs.
Carbon storage and delayed emissions: credits associated with temporary (carbon) storage or delayed emissions are not considered in the calculation of the Global Warming Potential impacts for the default impact categories.
Emissions off-setting: not included
Fossil and biogenic carbon emissions and removals: removals and emissions are modelled as follows: All GHG emissions from fossil fuels (including peat and limestone) are modelled consistently with the ILCD list of elementary flows. In the case that the emissions refer to the molecules CO2 and CH4, they are modelled as ‘carbon dioxide (fossil)’ and ‘methane (fossil)’. Biogenic uptake and emissions are modelled separately. For land use change, all carbon emissions and uptakes are inventoried separately for each of the elementary flows. Soil carbon accumulation (uptake) via improved agricultural management is excluded from the model.NoneGaBi Modelling PrinciplesGaBi Water Modelling PrinciplesGaBi Agriculture Model DocumentationGaBi Land Use Change Model DocumentationGaBi Energy Modelling PrinciplesGaBi Refinery Modelling PrinciplesOver 99% of mass and energy inputs and outputs to the overall process are included.
Cut-off rules for each unit process: Chemical inputs to wafer processing with unremarkable environmental relevance falling below 0.1% of input chemical flow by mass (excluding water inputs) are excluded. Chemical inputs lacking LCI data for their high-purity semiconductor grade form are represented using industrial grade purity. All process emissions with high environmental relevance are included in the inventory, no matter how low the mass contribution.
When considering only chemical inputs to the wafer fabrication (front-end) process (excluding the mass of water and silicon), coverage of at least 95 % of mass of the input flows are achieved. All process emissions with high global warming impact are included in the inventory, even when mass emissions fall below 0.1% because, at this point in time, not all high-GWP emissions are completely abated in semiconductor production worldwide.
For further details please see the document "GaBi Databases Modeling Principles."NoneAll environmentally-relevant mass inputs and emissions are included, where LCI data (for inputs) or characterization factors (for emissions) are available, but where a representative or proxy LCI data, or impact factor, is not available, the mass input is excluded. Where LCI data is not available for semiconductor grade (99.9998-99.99998%) chemicals, non-highly-pure (industrial grade) chemicals of 99-99.9% purity are used. Where an emissions factor for an exact chemical emission is not available, a representative group impact factor (e.g. NMVOC) is used.NoneFor details please see the document "GaBi Databases Modelling Principles"NoneSICAS Glob. Statistics Report 4th Quarter 2008: Integrated Circuit Wafer-Fab Capacity & UtilisationUltra-fine feature printed circuits and multi-chip modules. , 1995Average Industry Data , 1999-2010Patent-/ Technical Literature, 1999-2006Life-Cycle Assessment of Flash Memory.Life-cycle assessment of computational logic produced from 1995 through 2010.Life-cycle energy and global warming potential of computational logicThe 1.7 kilogram microchip: Energy and material use in the production of semiconductor devices.Case studies in energy use to realize ultra-high purities in semiconductor manufacturingSIA. Annual Forecast of Global Semiconductor Sales.Life-Cycle Assessment of SemiconductorsThe Int. Technology Roadmap for Semiconductors, 2001-2011 Editions and Updates. 2001-2011Life Cycle Assessment for Semiconductor Device, 2004An LCA approach to logic process customized by JEITA, 2004An LCA approach to Back-end Process of Logic LCI customized by JEITA , 2004JEITA STD. LOGIC PROCESS MODELING AND APPLICATION 3, 2006ESTIMATION METHOD OF LIFE CYCLE INVENTORY DATA FOR SEMICONDUCTOR DEVICES, 2006INTEGRATION OF ENERGY AND OPERATING MATERIAL SERVICE SYSTEMS IN AREA-BASED JEITA MODEL , 2006EXAMPLE “LCI”CALCULATION OF SEMICONDUCTOR DEVICES, USED FOR VIDEO CAMERA, THOSE MOUNTED ON THE PRINT95.0noneThe dataset represents an aggregated process with cradle-to-gate system boundaries.
Select components and processes by type, size, mass and housing design, which is most suitable to reflect the product under consideration. In case the suitable component is not available, a scaling according to mass and size of the most appropriate component can be applied, e.g. scaling 1.5 pieces in the model to reflect 3 smaller pieces in the product. The dataset can be linked to the component mixer and scaled via parameter by piece, by mass, by size.
Dataset should be used in combination with an assembly line dataset (mounting of the device via surface mounting or through-hole technology) and a substrate (e.g. printed wiring board) dataset. The dataset can be connected to the unit process Component mixer or Component mixer (DfX). For an example see the plan Populated printed wiring board.All relevant flows quantifiedAnthropogenic Abiotic Depletion Potential (AADP), TU BerlinCML2001 - Jan. 2016, Abiotic Depletion (ADP elements)CML2001 - Jan. 2016, Abiotic Depletion (ADP fossil)CML2001 - Jan. 2016, Acidification Potential (AP)CML2001 - Jan. 2016, Eutrophication Potential (EP)CML2001 - Jan. 2016, Freshwater Aquatic Ecotoxicity Pot. (FAETP inf.)CML2001 - Jan. 2016, Global Warming Potential (GWP 100 years)CML2001 - Jan. 2016, Global Warming Potential (GWP 100 years), excl biogenic carbonCML2001 - Jan. 2016, Human Toxicity Potential (HTP inf.)CML2001 - Jan. 2016, Marine Aquatic Ecotoxicity Pot. (MAETP inf.)CML2001 - Jan. 2016, Ozone Layer Depletion Potential (ODP, steady state)CML2001 - Jan. 2016, Photochem. Ozone Creation Potential (POCP)CML2001 - Jan. 2016, Terrestric Ecotoxicity Potential (TETP inf.)CML2001 - Jan. 2016, Global Warming Potential (GWP 100), excl bio. C, incl LUC, no norm/weightCML2001 - Jan. 2016, Global Warming Potential (GWP 100), incl bio. C, incl LUC, no norm/weightCML2001 - Jan. 2016, Global Warming Potential (GWP 100), Land Use Change only, no norm/weightCML2001 - Jan. 2016, Abiotic Depletion (ADP elements), Economic ReserveCML2001 - Jan. 2016, Abiotic Depletion (ADP elements), Reserve BaseEF 2.0 AcidificationEF 2.0 Human toxicity, cancerEF 2.0 Climate Change - totalEF 2.0 Ecotoxicity, freshwaterEF 2.0 Eutrophication, freshwaterEF 2.0 Eutrophication, marineEF 2.0 Eutrophication, terrestrialEF 2.0 Ionising radiation, human healthEF 2.0 Land UseEF 2.0 Human toxicity, non-cancerEF 2.0 Ozone depletionEF 2.0 Photochemical ozone formation, human healthEF 2.0 Resource use, fossilsEF 2.0 Resource use, mineral and metalsEF 2.0 Particulate matterEF 2.0 Water useReCiPe 2016 v1.1 Midpoint (E) - Terrestrial ecotoxicityReCiPe 2016 v1.1 Midpoint (E) - Freshwater ecotoxicityReCiPe 2016 v1.1 Midpoint (E) - Marine ecotoxicityReCiPe 2016 v1.1 Midpoint (E) - Human toxicity, non-cancerReCiPe 2016 v1.1 Midpoint (E) - Human toxicity, cancerReCiPe 2016 v1.1 Midpoint (E) - Climate change, incl biogenic carbonReCiPe 2016 v1.1 Midpoint (E) - Climate change, default, excl biogenic carbonReCiPe 2016 v1.1 Midpoint (E) - Metal depletionReCiPe 2016 v1.1 Midpoint (E) - Photochemical Ozone Formation, Human HealthReCiPe 2016 v1.1 Midpoint (E) - Photochemical Ozone Formation, EcosystemsReCiPe 2016 v1.1 Midpoint (E) - Fossil depletionReCiPe 2016 v1.1 Midpoint (E) - Freshwater ConsumptionReCiPe 2016 v1.1 Midpoint (E) - Stratospheric Ozone DepletionReCiPe 2016 v1.1 Midpoint (E) - Fine Particulate Matter FormationReCiPe 2016 v1.1 Midpoint (E) - Terrestrial AcidificationReCiPe 2016 v1.1 Midpoint (E) - Ionizing RadiationReCiPe 2016 v1.1 Midpoint (E) - Freshwater EutrophicationReCiPe 2016 v1.1 Midpoint (E) - Land useReCiPe 2016 v1.1 Midpoint (E) - Marine EutrophicationReCiPe 2016 v1.1 Midpoint (E) - Climate change, excl biog. C, incl LUC, no norm/weightReCiPe 2016 v1.1 Midpoint (E) - Climate change, incl biog. C, incl LUC, no norm/weightReCiPe 2016 v1.1 Endpt(E) - Climate change Terrest Ecosystems, excl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(E) - Climate change Human Health, excl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(E) - Climate change Freshw Ecosystems, excl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(E) - Climate change Terrest Ecosystems, incl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(E) - Climate change Human Health, incl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(E) - Climate change Freshw Ecosystems, incl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(E) - Climate change Freshw Ecosystems, LUC only, no norm/weightReCiPe 2016 v1.1 Endpt(E) - Climate change Human Health, LUC only, no norm/weightReCiPe 2016 v1.1 Midpoint (E) - Climate change, LUC only, no norm/weightReCiPe 2016 v1.1 Endpt(E) - Climate change Terrest Ecosystems, LUC only, no norm/weightReCiPe 2016 v1.1 Endpoint (E) - Terrestrial ecotoxicityReCiPe 2016 v1.1 Endpoint (E) - Freshwater ecotoxicityReCiPe 2016 v1.1 Endpoint (E) - Marine ecotoxicityReCiPe 2016 v1.1 Endpoint (E) - Human toxicity, non-cancerReCiPe 2016 v1.1 Endpoint (E) - Human toxicity, cancerReCiPe 2016 v1.1 Endpoint (E) - Climate change Freshw Ecosystems, default, excl biogenic carbonReCiPe 2016 v1.1 Endpoint (E) - Climate change Human Health, default, excl biogenic carbonReCiPe 2016 v1.1 Endpoint (E) - Climate change Terrest Ecosystems, default, excl biogenic carbonReCiPe 2016 v1.1 Endpoint (E) - Climate change Terrest Ecosystems, incl biogenic carbonReCiPe 2016 v1.1 Endpoint (E) - Climate Change Human Health, incl biogenic carbonReCiPe 2016 v1.1 Endpoint (E) - Climate change Freshw Ecosystems, incl biogenic carbonReCiPe 2016 v1.1 Endpoint (E) - Metal depletionReCiPe 2016 v1.1 Endpoint (E) - Photochemical Ozone Formation, Human HealthReCiPe 2016 v1.1 Endpoint (E) - Photochemical Ozone Formation, EcosystemsReCiPe 2016 v1.1 Endpoint (E) - Fossil depletionReCiPe 2016 v1.1 Endpoint (E) - Freshwater Consumption, Human HealthReCiPe 2016 v1.1 Endpoint (E) - Freshwater Consumption, Terrest EcosystemsReCiPe 2016 v1.1 Endpoint (E) - Freshwater Consumption, Freshw EcosystemsReCiPe 2016 v1.1 Endpoint (E) - Stratospheric Ozone DepletionReCiPe 2016 v1.1 Endpoint (E) - Fine Particulate Matter FormationReCiPe 2016 v1.1 Endpoint (E) - Terrestrial AcidificationReCiPe 2016 v1.1 Endpoint (E) - Ionizing RadiationReCiPe 2016 v1.1 Endpoint (E) - Freshwater EutrophicationReCiPe 2016 v1.1 Endpoint (E) - Land useReCiPe 2016 v1.1 Endpoint (E) - Marine EutrophicationReCiPe 2016 v1.1 Midpoint (H) - Terrestrial ecotoxicityReCiPe 2016 v1.1 Midpoint (H) - Freshwater ecotoxicityReCiPe 2016 v1.1 Midpoint (H) - Marine ecotoxicityReCiPe 2016 v1.1 Midpoint (H) - Human toxicity, non-cancerReCiPe 2016 v1.1 Midpoint (H) - Human toxicity, cancerReCiPe 2016 v1.1 Midpoint (H) - Climate change, default, excl biogenic carbonReCiPe 2016 v1.1 Midpoint (H) - Climate change, incl biogenic carbonReCiPe 2016 v1.1 Midpoint (H) - Metal depletionReCiPe 2016 v1.1 Midpoint (H) - Photochemical Ozone Formation, Human HealthReCiPe 2016 v1.1 Midpoint (H) - Photochemical Ozone Formation, EcosystemsReCiPe 2016 v1.1 Midpoint (H) - Fossil depletionReCiPe 2016 v1.1 Midpoint (H) - Freshwater ConsumptionReCiPe 2016 v1.1 Midpoint (H) - Stratospheric Ozone DepletionReCiPe 2016 v1.1 Midpoint (H) - Fine Particulate Matter FormationReCiPe 2016 v1.1 Midpoint (H) - Terrestrial AcidificationReCiPe 2016 v1.1 Midpoint (H) - Ionizing RadiationReCiPe 2016 v1.1 Midpoint (H) - Freshwater EutrophicationReCiPe 2016 v1.1 Midpoint (H) - Land useReCiPe 2016 v1.1 Midpoint (H) - Marine EutrophicationReCiPe 2016 v1.1 Midpoint (H) - Climate change, excl biog. C, incl LUC, no norm/weightReCiPe 2016 v1.1 Endpt(H) - Climate change Terrest Ecosystems, excl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(H) - Climate change Human Health, excl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(H) - Climate change Freshw Ecosystems, excl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Midpoint (H) - Climate change, incl biog. C, incl LUC, no norm/weightReCiPe 2016 v1.1 Endpt(H) - Climate change Terrest Ecosystems, incl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(H) - Climate change Human Health, incl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(H) - Climate change Freshw Ecosystems, incl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(H) - Climate change Freshw Ecosystems, LUC only, no norm/weightReCiPe 2016 v1.1 Endpt(H) - Climate change Human Health, LUC only, no norm/weightReCiPe 2016 v1.1 Midpoint (H) - Climate change, LUC only, no norm/weightReCiPe 2016 v1.1 Endpt(H) - Climate change Terrest Ecosystems, LUC only, no norm/weightReCiPe 2016 v1.1 Endpoint (H) - Terrestrial ecotoxicityReCiPe 2016 v1.1 Endpoint (H) - Freshwater ecotoxicityReCiPe 2016 v1.1 Endpoint (H) - Marine ecotoxicityReCiPe 2016 v1.1 Endpoint (H) - Human toxicity, non-cancerReCiPe 2016 v1.1 Endpoint (H) - Human toxicity, cancerReCiPe 2016 v1.1 Endpoint (H) - Climate change Freshw Ecosystems, default, excl biogenic carbonReCiPe 2016 v1.1 Endpoint (H) - Climate change Human Health, default, excl biogenic carbonReCiPe 2016 v1.1 Endpoint (H) - Climate change Terrest Ecosystems, default, excl biogenic carbonReCiPe 2016 v1.1 Endpoint (H) - Climate change Terrest Ecosystems, incl biogenic carbonReCiPe 2016 v1.1 Endpoint (H) - Climate change Human Health, incl biogenic carbonReCiPe 2016 v1.1 Endpoint (H) - Climate change Freshw Ecosystems, incl biogenic carbonReCiPe 2016 v1.1 Endpoint (H) - Metal depletionReCiPe 2016 v1.1 Endpoint (H) - Photochemical Ozone Formation, Human HealthReCiPe 2016 v1.1 Endpoint (H) - Photochemical Ozone Formation, EcosystemsReCiPe 2016 v1.1 Endpoint (H) - Fossil depletionReCiPe 2016 v1.1 Endpoint (H) - Freshwater Consumption, Human HealthReCiPe 2016 v1.1 Endpoint (H) - Freshwater Consumption, Terrest EcosystemsReCiPe 2016 v1.1 Endpoint (H) - Freshwater Consumption, Freshw EcosystemsReCiPe 2016 v1.1 Endpoint (H) - Stratospheric Ozone DepletionReCiPe 2016 v1.1 Endpoint (H) - Fine Particulate Matter FormationReCiPe 2016 v1.1 Endpoint (H) - Terrestrial AcidificationReCiPe 2016 v1.1 Endpoint (H) - Ionizing RadiationReCiPe 2016 v1.1 Endpoint (H) - Freshwater EutrophicationReCiPe 2016 v1.1 Endpoint (H) - Land useReCiPe 2016 v1.1 Endpoint (H) - Marine EutrophicationReCiPe 2016 v1.1 Midpoint (I) - Terrestrial ecotoxicityReCiPe 2016 v1.1 Midpoint (I) - Freshwater ecotoxicityReCiPe 2016 v1.1 Midpoint (I) - Marine ecotoxicityReCiPe 2016 v1.1 Midpoint (I) - Human toxicity, non-cancerReCiPe 2016 v1.1 Midpoint (I) - Climate change, default, excl biogenic carbonReCiPe 2016 v1.1 Midpoint (I) - Climate change, incl biogenic carbonReCiPe 2016 v1.1 Midpoint (I) - Metal depletionReCiPe 2016 v1.1 Midpoint (I) - Photochemical Ozone Formation, Human HealthReCiPe 2016 v1.1 Midpoint (I) - Photochemical Ozone Formation, EcosystemsReCiPe 2016 v1.1 Midpoint (I) - Fossil depletionReCiPe 2016 v1.1 Midpoint (I) - Human toxicity, cancerReCiPe 2016 v1.1 Midpoint (I) - Freshwater ConsumptionReCiPe 2016 v1.1 Midpoint (I) - Stratospheric Ozone DepletionReCiPe 2016 v1.1 Midpoint (I) - Fine Particulate Matter FormationReCiPe 2016 v1.1 Midpoint (I) - Terrestrial AcidificationReCiPe 2016 v1.1 Midpoint (I) - Ionizing RadiationReCiPe 2016 v1.1 Midpoint (I) - Freshwater EutrophicationReCiPe 2016 v1.1 Midpoint (I) - Land useReCiPe 2016 v1.1 Midpoint (I) - Marine EutrophicationReCiPe 2016 v1.1 Midpoint (I) - Climate change, excl biog. C, incl LUC, no norm/weightReCiPe 2016 v1.1 Endpt(I) - Climate change Terrest Ecosystems, excl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(I) - Climate change Human Health, excl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(I) - Climate change Freshw Ecosystems, excl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Midpoint (I) - Climate change, incl biog. C, incl LUC, no norm/weightReCiPe 2016 v1.1 Endpt(I) - Climate change Terrest Ecosystems, incl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(I) - Climate change Human Health, incl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(I) - Climate change Freshw Ecosystems, incl biog. C, incl LUC, no norm/weighReCiPe 2016 v1.1 Endpt(I) - Climate change Freshw Ecosystems, LUC only, no norm/weightReCiPe 2016 v1.1 Endpt(I) - Climate change Human Health, LUC only, no norm/weightReCiPe 2016 v1.1 Midpoint (I) - Climate change, LUC only, no norm/weightReCiPe 2016 v1.1 Endpt(I) - Climate change Terrest Ecosystems, LUC only, no norm/weightReCiPe 2016 v1.1 Endpoint (I) - Terrestrial ecotoxicityReCiPe 2016 v1.1 Endpoint (I) - Freshwater ecotoxicityReCiPe 2016 v1.1 Endpoint (I) - Marine ecotoxicityReCiPe 2016 v1.1 Endpoint (I) - Human toxicity, non-cancerReCiPe 2016 v1.1 Endpoint (I) - Climate change Freshw Ecosystems, default, excl biogenic carbonReCiPe 2016 v1.1 Endpoint (I) - Climate change Human Health, default, excl biogenic carbonReCiPe 2016 v1.1 Endpoint (I) - Climate change Terrest Ecosystems, default, excl biogenic carbonReCiPe 2016 v1.1 Endpoint (I) - Climate change Terrest Ecosystems, incl biogenic carbonReCiPe 2016 v1.1 Endpoint (I) - Climate change Human Health, incl biogenic carbonReCiPe 2016 v1.1 Endpoint (I) - Climate change Freshw Ecosystems, incl biogenic carbonReCiPe 2016 v1.1 Endpoint (I) - Metal depletionReCiPe 2016 v1.1 Endpoint (I) - Photochemical Ozone Formation, Human HealthReCiPe 2016 v1.1 Endpoint (I) - Photochemical Ozone Formation, EcosystemsReCiPe 2016 v1.1 Endpoint (I) - Fossil depletionReCiPe 2016 v1.1 Endpoint (I) - Human toxicity, cancerReCiPe 2016 v1.1 Endpoint (I) - Freshwater Consumption, Human HealthReCiPe 2016 v1.1 Endpoint (I) - Freshwater Consumption, Terrest EcosystemsReCiPe 2016 v1.1 Endpoint (I) - Freshwater Consumption, Freshw EcosystemsReCiPe 2016 v1.1 Endpoint (I) - Stratospheric Ozone DepletionReCiPe 2016 v1.1 Endpoint (I) - Fine Particulate Matter FormationReCiPe 2016 v1.1 Endpoint (I) - Terrestrial AcidificationReCiPe 2016 v1.1 Endpoint (I) - Ionizing RadiationReCiPe 2016 v1.1 Endpoint (I) - Freshwater EutrophicationReCiPe 2016 v1.1 Endpoint (I) - Land useReCiPe 2016 v1.1 Endpoint (I) - Marine EutrophicationIPCC AR5 GWP20, incl cc fb, incl biogenic carbonIPCC AR5 GWP100, incl cc fb, incl biogenic carbonIPCC AR5 GTP50, incl cc fb, incl biogenic carbonIPCC AR5 GTP20, incl cc fb, incl biogenic carbonIPCC AR5 GTP100, incl cc fb, incl biogenic carbonIPCC AR5 GTP20, incl cc fb, incl biogenic carbon, Land Use Change only, no norm/weightIPCC AR5 GTP20, incl cc fb, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP50, incl cc fb, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GWP100, incl cc fb, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GWP100, incl cc fb, incl biogenic carbon, Land Use Change only, no norm/weightIPCC AR5 GTP100, incl cc fb, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP50, incl cc fb, incl biogenic carbon, Land Use Change only, no norm/weightIPCC AR5 GTP100, incl cc fb, incl biogenic carbon, Land Use Change only, no norm/weightIPCC AR5 GWP20, incl cc fb, incl biogenic carbon, Land Use Change only, no norm/weightIPCC AR5 GWP20, incl cc fb, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GWP20, incl cc fb, excl biogenic carbonIPCC AR5 GTP20, incl cc fb, excl biogenic carbonIPCC AR5 GWP100, incl cc fb, excl biogenic carbonIPCC AR5 GTP50, incl cc fb, excl biogenic carbonIPCC AR5 GTP100, incl cc fb, excl biogenic carbonIPCC AR5 GWP20, incl cc fb, excl biogenic carbon, Land Use Change only, no norm/weightIPCC AR5 GTP100, incl cc fb, excl biogenic carbon, Land Use Change only, no norm/weightIPCC AR5 GWP100, incl cc fb, excl biogenic carbon, Land Use Change only, no norm/weightIPCC AR5 GWP100, incl cc fb, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP20, incl cc fb, excl biogenic carbon, Land Use Change only, no norm/weightIPCC AR5 GWP20, incl cc fb, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP100, incl cc fb, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP50, incl cc fb, excl biogenic carbon, Land Use Change only, no norm/weightIPCC AR5 GTP50, incl cc fb, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP20, incl cc fb, excl biogenic carbon, incl Land Use Change, no norm/weightLANCA v2.3, Biotic Production Loss Potential (Occupation)LANCA v2.3, Biotic Production Loss Potential (Transformation)LANCA v2.3, Erosion Potential (Occupation)LANCA v2.3, Erosion Potential (Transformation)LANCA v2.3, Groundwater Regeneration Reduction Potential (Occupation)LANCA v2.3, Groundwater Regeneration Reduction Potential (Transformation)LANCA v2.3, Infiltration Reduction Potential (Occupation)LANCA v2.3, Infiltration Reduction Potential (Transformation)LANCA v2.3, Physicochemical Filtration Reduction Potential (Occupation)LANCA v2.3, Physicochemical Filtration Reduction Potential (Transformation)TRACI 2.1, Global Warming Air, incl. biogenic carbonTRACI 2.1, Resources, Fossil fuelsTRACI 2.1, Human toxicity, cancer (recommended)TRACI 2.1, Human toxicity, non-canc. (recommended)TRACI 2.1, Global Warming Air, excl. biogenic carbonTRACI 2.1, Smog AirTRACI 2.1, Ecotoxicity (recommended)TRACI 2.1, AcidificationTRACI 2.1, EutrophicationTRACI 2.1, Human Health Particulate AirTRACI 2.1, Ozone Depletion AirTRACI 2.1, Global Warming Air, excl biogenic carbon, incl LUC, no norm/weightTRACI 2.1, Global Warming Air, LUC only, no norm/weightTRACI 2.1, Global Warming Air, incl biogenic carbon, incl LUC, no norm/weightUBP 2013, Carcinogenic substances into airUBP 2013, Energy resourcesUBP 2013, Global warmingUBP 2013, Heavy metals into airUBP 2013, Heavy metals into soilUBP 2013, Heavy metals into waterUBP 2013, Land useUBP 2013, Main air pollutantsUBP 2013, Mineral resourcesUBP 2013, Non radioactive waste to depositUBP 2013, Ozone layer depletionUBP 2013, Pesticides into soilUBP 2013, POP into waterUBP 2013, Radioactive substances into airUBP 2013, Radioactive substances into waterUBP 2013, Radioactive waste to depositUBP 2013, Water pollutantsUBP 2013, Water resourcesUBP 2013, Global warming, incl Land Use ChangeUBP 2013, Global warming, Land Use Change onlyUSEtox 2.1, Ecotoxicity (recommended and interim)USEtox 2.1, Ecotoxicity (recommended only)USEtox 2.1, Human toxicity, cancer (recommended and interim)USEtox 2.1, Human toxicity, cancer (recommended only)USEtox 2.1, Human toxicity, non-canc. (recommended and interim)USEtox 2.1, Human toxicity, non-canc. (recommended only)AWARE, high characterization factor for unspecified waterAWARE, low characterization factor for unspecified waterAWARE, OECD+BRIC average for unspecified waterBlue water consumptionBlue water useTotal freshwater consumption (including rainwater)Total freshwater useWSI, high characterization factor for unspecified waterWSI, low characterization factor for unspecified waterWSI, OECD+BRIC average for unspecified waterAWARE (excl hydropower), high characterization factor for unspecified waterAWARE (excl hydropower), low characterization factor for unspecified waterAWARE (excl hydropower), OECD+BRIC average for unspecified waterBlue water consumption (excl hydropower)Blue water use (excl hydropower)Total freshwater consumption (excl hydropower, including rainwater)Total freshwater use (excl hydropower)WSI (excl hydropower), high characterization factor for unspecified waterWSI (excl hydropower), low characterization factor for unspecified waterWSI (excl hydropower), OECD+BRIC average for unspecified waterThe LCI method applied is in compliance with ISO 14040 and 14044. The documentation includes all relevant information in view of the data quality and scope of the application of the respective LCI result / data set. The dataset represents the state-of-the-art in view of the referenced functional unit.Sphera Solutions GmbHIABP-GaBiGaBi user forumOverall quality according to different validation schemes
GaBi = 1,8 interpreted into "good overall quality" in the GaBi quality validation scheme
ILCD = 1,9 interpreted into "basic overall quality" in the ILCD quality validation scheme
PEF = 1,8 interpreted into "very good overall quality" in the PEF quality validation schemeThe dataset and systems, which are provided with our software and databases for public use into a broad user community, are constantly used, compared, benchmarked, screened, reviewed and results published in various external, professional and third party LCA applications in industry, academia and politics. So user feedback via the online GaBi forum or direct via user information is a standard routine in the maintenance and update process and leads to stable quality and constant control and improvement of data, if knowledge or technology improves or industrial process chains develop or change.GaBi bug forumFraunhofer IBPGaBi user communityGaBi conformity systemFully compliantFully compliantFully compliantFully compliantFully compliantNot definedUNEP SETAC Life Cycle InitiativeNot definedNot definedNot definedNot definedNot definedNot definedILCD Data Network - Entry-levelNot definedFully compliantFully compliantNot definedFully compliantNot definedSphera Solutions GmbHThis background LCI data set can be used for any types of LCA studies.Sphera Solutions GmbH2022-03-01T00:00:00.000ILCD format 1.1Sphera Solutions GmbHNo official approval by producer or operator2022-03-01T00:00:00.00000.00.001Data set finalised; entirely publishedGaBi databasesSphera Solutions GmbHtrueOtherGaBi (source code, database including extension modules and single data sets, documentation) remains property of Sphera Solutions GmbH. Sphera Solutions GmbH delivers GaBi licenses comprising data storage medium and manual as ordered by the customer. The license guarantees the right of use for one installation of GaBi. Further installations using the same license are not permitted. Additional licenses are only valid if the licensee holds at least one main license. Licenses are not transferable and must only be used within the licensee's organisation. Data sets may be copied for internal use. The number of copies is restricted to the number of licenses of the software system GaBi the licensee owns. The right of use is exclusively valid for the licensee. All rights reserved.Transistor power THT/SMD SOT93/TO218 3 leads (4.70g) 15.5x12.9x4.7Output1.01.00.000Mixed primary / secondaryCalculatedvaluable