{ "help": "Return the metadata of a dataset (package) and its resources. :param id: the id or name of the dataset :type id: string", "success": true, "result": { "id": "60dbcdd4-8be4-4f41-896c-e725bdb37fe2", "url": "https://www.inptdat.de/node/72", "source": { "name": "CCP", "specification": "AC, high frequency, low pressure, non-thermal", "properties": "

Low-pressure RF plasma between plane electrodes separated by the distance d, driven by a sinusoidal voltage with amplitude V0 and frequency f; d = 2.5 cm (argon) resp. 6.7 cm (helium); V0 = 50-250 V; f = 13.56 MHz; Current density: 10 A/m^2

\n" }, "medium": { "name": "He, Ar", "properties": "

Gas temperature: 300 K; Pressure: 10-80 Pa

\n" }, "target": [], "diagnostics": { "name": "fluid-Poisson model, pic-mcc simulation", "properties": "

The fluid description of the electron component is performed by means of two different drift-diffusion approaches: the novel drift-diffusion model DDAn introduced in Becker and Loffhagen 2013 (https://doi.org/10.1063/1.4775771) and the commonly used classical drift-diffusion model DDA53 using simplified electron energy transport coefficients. Details of both fluid modelling approaches are given in Becker et al. 2017 (https://doi.org/10.1088/1361-6595/aa5cce). For ions, a time-dependent two-moment model is applied. It takes into account the continuity equation and the momentum balance equation, see Becker et al. 2017 for details. In addition to the fluid modeling approaches, two PIC-MCC simulation codes were developed independently and are applied for mutual verification and benchmarking of the different fluid models for the parameter range considered. Details of the PIC/MCC simulation procedures as well as used cross sections and other input data are given in Becker et al. 2017.

\n" }, "resource": [ { "id": "ceb3f641-fa38-4165-9c67-0ebb517d4c32", "url": "https://www.inptdat.de/system/files/node72_data-table_Ni_Ar20Pa_0.csv", "filetype": "csv", "datatype": "data table", "range": "Gas: argon at 20 Pa", "quality": "verified" }, { "id": "0276f0b1-b839-4500-972b-bed5d0b9c130", "url": "https://www.inptdat.de/system/files/node72_data-table_Ni_Ar40Pa.csv", "filetype": "csv", "datatype": "data table", "range": "Gas: argon at 40 Pa", "quality": "verified" }, { "id": "5d2db3a0-78ed-40b2-991a-544381cbd1d5", "url": "https://www.inptdat.de/system/files/node72_data-table_Ni_Ar80Pa.csv", "filetype": "csv", "datatype": "data table", "range": "Gas: argon at 80 Pa", "quality": "verified" }, { "id": "70bb6a33-a2b3-4884-a221-494f6d8fa69f", "url": "https://www.inptdat.de/system/files/node72_data-table_Ni_He10Pa.csv", "filetype": "csv", "datatype": "data table", "range": "Gas: helium at 10 Pa", "quality": "verified" }, { "id": "45a84df9-3f12-43fc-ba28-6577f07640d2", "url": "https://www.inptdat.de/system/files/node72_data-table_Ni_He20Pa.csv", "filetype": "csv", "datatype": "data table", "range": "Gas: helium at 20 Pa", "quality": "verified" }, { "id": "b7e0877d-031e-4559-8170-bf3720e27d4c", "url": "https://www.inptdat.de/system/files/node72_data-table_Ni_He40Pa.csv", "filetype": "csv", "datatype": "data table", "range": "Gas: helium at 40 Pa", "quality": "verified" }, { "id": "3c428028-5fdc-4ef2-9772-d3f26d4dfc87", "url": "https://www.inptdat.de/system/files/node72_data-table_Ni_He80Pa.csv", "filetype": "csv", "datatype": "data table", "range": "Gas: helium at 80 Pa", "quality": "verified" } ] } }