{"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":"4955b752-4fc5-4eb8-90b4-8e8a9f296451","name":"mcplas-matlab-toolbox-reproducible-plasma-modelling-comsol-dataset","title":"MCPlas, a MATLAB toolbox for reproducible plasma modelling with COMSOL - dataset","author":"DO NOT USE","author_email":"marjan.stankov@inp-greifswald.de","maintainer":"INPTDAT \u2013 The Data Platform for Plasma Technology","maintainer_email":"wissenschafts-it@inp-greifswald.de","license_title":"https:\/\/creativecommons.org\/licenses\/by\/4.0\/","notes":"\u003Cp\u003EThe dataset contains all input data and results of the MCPlas toolbox presented in the publication [\u003Ca href=\u0022https:\/\/doi.org\/10.1016\/j.cpc.2026.110248\u0022\u003Ehttps:\/\/doi.org\/10.1016\/j.cpc.2026.110248\u003C\/a\u003E]. The MCPlas toolbox represents a collection of MATLAB functions for the automated generation of an equation-based fluid-Poisson model for non-thermal plasmas in the multiphysics simulation software COMSOL. Following the development of the new generation of the LXCat platform, all input data are prepared in a structured and interoperable JSON format and can be supplied and validated using existing JSON schemas. The toolbox includes fully transparent, editable MATLAB source code and offers an advanced description of electron transport in addition to commonly used approaches in the plasma modelling community. It supports one-dimensional and two-dimensional modelling geometries employing Cartesian, polar and cylindrical coordinate systems. MCPlas is tested on two reference cases: DC- and RF-driven low-pressure glow discharges in argon.\u003C\/p\u003E\n","url":"https:\/\/www.inptdat.de\/dataset\/mcplas-matlab-toolbox-reproducible-plasma-modelling-comsol-dataset","state":"Active","log_message":"Update to resource MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 9: CPM modelling results using 4-species RKM for DC case","private":true,"revision_timestamp":"Mon, 06\/15\/2026 - 00:00","metadata_created":"Mon, 02\/23\/2026 - 11:12","metadata_modified":"Mon, 06\/15\/2026 - 00:00","creator_user_id":"0e27023c-5517-4b3f-b96e-c939dc6a74ff","type":"Dataset","resources":[{"id":"c75cc6b4-22d2-4017-9486-9873b9ab4127","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_9_CPM.csv","description":"\u003Cp\u003EModelling results obtained with CPM using the 4-species RKM (reaction kinetic model).  Data contain species number densities, mean electron energy and electric field in the stationary state of the discharge. Modelling was carried out for a constant voltage of 350\u202fV, with a gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 9: CPM modelling results using 4-species RKM for DC case","mimetype":"text\/csv","size":"97.05 KB","created":"Mon, 06\/08\/2026 - 00:15","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"be958eb8-06f5-481d-90f5-83f3164d98f3","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_9_MCPlas_0.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas using the 4-species RKM (reaction kinetic model). Data contain species number densities, mean electron energy and electric field in the stationary state of the discharge. Modelling was carried out for a constant voltage of 350\u202fV, with a gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 9: MCPlas modelling results using 4-species RKM for DC case","mimetype":"text\/csv","size":"97.03 KB","created":"Mon, 06\/08\/2026 - 00:17","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"872c8f6d-c903-4fdb-baf8-82b59eee3878","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_10_CPM.csv","description":"\u003Cp\u003EModelling results obtained with CPM using the 4-species RKM (reaction kinetic model). Data contain species number densities, mean electron energy and electric field in the stationary state of the discharge. Modelling was carried out for a constant voltage of 350\u202fV, with a gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 10: CPM modelling results using 4-species RKM for DC case","mimetype":"text\/csv","size":"97.05 KB","created":"Mon, 06\/08\/2026 - 00:20","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"14f29603-f605-4825-b0e7-1758f43bd131","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_10_MCPlas_0.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas using the 4-species RKM (reaction kinetic model), option DDAn (improved drift-diffusion approximation) and boundary conditions (10), (11) and (14) from the manuscript. Data contain particle species number densities,  mean electron energy and electric in the stationary state of a DC glow discharge in argon . Modelling was carried out for a constant voltage of 350\u202fV, with a gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 10: MCPlas modelling results using 4-species RKM for DC case","mimetype":"text\/csv","size":"96.57 KB","created":"Mon, 06\/08\/2026 - 00:42","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"76aca40d-365b-4230-9d7a-cbcc27fa0ed0","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_11_CPM.csv","description":"\u003Cp\u003EModelling results obtained with CPM using the 4-species RKM (reaction kinetic model).  Data contain period-averaged particle species number densities, mean electron energy and electric field. Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz. A gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK were also considered in the modelling.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 11:  CPM modelling results using 4-species RKM for RF case","mimetype":"text\/csv","size":"99.21 KB","created":"Mon, 06\/08\/2026 - 00:44","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"15a2522b-e6f2-45f7-99b6-4760d6e10998","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_11_MCPlas.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas using the 4-species RKM (reaction kinetic model).  Data contain period-averaged particle species number densities, mean electron energy and electric field. Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz. A gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK were also considered in the modelling.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 11: MCPlas modelling results using 4-species RKM for RF case","mimetype":"text\/csv","size":"99.09 KB","created":"Mon, 06\/08\/2026 - 00:46","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"89fce69f-e95d-4378-bd46-43a0becc2f58","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_12_CPM.csv","description":"\u003Cp\u003EModelling results obtained with CPM for the 4-species RKM (reaction kinetic model).  Data contain period-averaged particle species number densities, mean electron energy and electric field. Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz. A gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK were also considered in the modelling.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 12: CPM modelling results using 4-species RKM for RF case","mimetype":"text\/csv","size":"99.21 KB","created":"Mon, 06\/08\/2026 - 00:48","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"1245ba14-59c1-43bb-9f25-54c0d1f5baca","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_12_MCPlas.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas using the 4-species RKM (reaction kinetic model), option DDAn (improved drift-diffusion approximation) and boundary conditions (10), (11) and (14) from the manuscript.   Data contain period-averaged particle species number densities, mean electron energy and electric field. Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz. A gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK were also considered in the modelling.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 12: MCPlas modelling results using 4-species RKM for RF case","mimetype":"text\/csv","size":"313.08 KB","created":"Mon, 06\/08\/2026 - 00:50","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"8c87e5a8-3d22-4d84-ae08-ae56d460dc08","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_13_4specRKM.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas using the 4-species RKM (reaction kinetic model), option DDAn (improved drift-diffusion approximation) and boundary conditions (10), (11) and (14) from the manuscript.  The data contain number densities of electrons and atomic argon ions, mean electron energy and number densities of metastable argon states in the stationary state of the DC glow discharge. Modelling was carried out for a constant voltage of 350\u202fV, with a gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr, and a gas temperature of 300\u202fK.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 13: MCPlas modelling results using 4-species RKM for DC case","mimetype":"text\/csv","size":"80.03 KB","created":"Mon, 06\/08\/2026 - 00:53","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"82c1c841-68d5-47b2-b705-e44b0cc21972","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_13_23specRKM.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas using the 23-species RKM (reaction kinetic model), option DDAn (improved drift-diffusion approximation) and boundary conditions (10), (11) and (14) from the manuscript.  The data contain number densities of electrons and atomic argon ions, mean electron energy and number densities of metastable argon states in the stationary state of the DC glow discharge. Modelling was carried out for a constant voltage of 350\u202fV, with a gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr, and a gas temperature of 300\u202fK.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 13: MCPlas modelling results using 23-species RKM for DC case","mimetype":"text\/csv","size":"157.26 KB","created":"Mon, 06\/08\/2026 - 00:54","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"9a2fd336-f699-4fc1-ae33-61ee18904cf4","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_14_4specRKM.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas using the 4-species RKM (reaction kinetic model), option DDAn (improved drift-diffusion approximation) and boundary conditions (10), (11) and (14) from the manuscript.  The data contain period-averaged number densities of electrons and atomic argon ions, mean electron energy and number densities of metastable argon states in the stationary state of the RF glow discharge. Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz. A gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr, and a gas temperature of 300\u202fK were also considered in the modelling.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 14: MCPlas modelling results using 4-species RKM for RF case","mimetype":"text\/csv","size":"263.6 KB","created":"Mon, 06\/08\/2026 - 00:56","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"5cec6dc8-17d2-4ba4-a4d5-ef3cb32375f2","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_14_23specRKM.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas for the 23-species RKM (reaction kinetic model), option DDAn (improved drift-diffusion approximation) and boundary conditions (10), (11) and (14) from the manuscript.  The data contain period-averaged number densities of electrons and atomic argon ions, mean electron energy and number densities of metastable argon states in the stationary state of the RF glow discharge. Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz. A gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr, and a gas temperature of 300\u202fK were also considered in the modelling.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 14: MCPlas modelling results using 23-species RKM for RF case","mimetype":"text\/csv","size":"269.59 KB","created":"Mon, 06\/08\/2026 - 00:58","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"f7f66015-396f-4277-9f1c-c3c78f20d049","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_15_23specRKM_DC.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas for the 23-species RKM (reaction kinetic model), option DDAn (improved drift-diffusion approximation) and boundary conditions (10), (11) and (14) from the manuscript.  The data contain number densities of excited molecular states and molecular ion in the stationary state of the DC glow discharge. Modelling was carried out for a constant voltage of 350\u202fV, with a gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr, and a gas temperature of 300\u202fK.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 15: MCPlas modelling results using 23-species RKM for DC case","mimetype":"text\/csv","size":"175.86 KB","created":"Mon, 06\/08\/2026 - 10:03","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"873fa1f1-a5fc-4ad2-b430-c8a81fd32751","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_15_23specRKM_RF.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas for the 23-species RKM (reaction kinetic model), option DDAn (improved drift-diffusion approximation) and boundary conditions (10), (11) and (14) from the manuscript.  The data contain period-averaged number densities of excited molecular states and molecular ion in the stationary state of the RF glow discharge. Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz. A gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr, and a gas temperature of 300\u202fK were also considered in the modelling.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 15: MCPlas modelling results using 23-species RKM for RF case","mimetype":"text\/csv","size":"297.1 KB","created":"Mon, 06\/08\/2026 - 10:05","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"8498f53d-26e8-49ab-8623-d8dd3d884fbf","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_16_4specRKM_DC_MCPlas.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas using the 4-species RKM (reaction kinetic model). The data contains  the density and mean energy of electrons as well as the density of heavy-particle species in stationary state of the DC  glow discharges in argon. Modelling was carried out for a constant voltage of 350\u202fV, with a gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 16: MCPlas modelling results using 4-species RKM for DC case","mimetype":"text\/csv","size":"80.51 KB","created":"Mon, 06\/08\/2026 - 10:21","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"a3af4eff-20bb-4583-a33b-7c4c3c8f9bc4","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_16_4specRKM_DC_FEDM_0.csv","description":"\u003Cp\u003EModelling results obtained with FEDM using the 4-species RKM (reaction kinetic model). The data contains  the density and mean energy of electrons as well as the density of heavy-particle species in stationary state of the DC  glow discharges in argon. Modelling was carried out for a constant voltage of 350\u202fV, with a gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 16: FEDM modelling results using 4-species RKM for DC case","mimetype":"text\/csv","size":"49 KB","created":"Mon, 06\/08\/2026 - 10:23","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"69f323e8-2e03-48c7-ab56-dfa2955cd000","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_16_4specRKM_DC_PLASIMO.csv","description":"\u003Cp\u003EModelling results obtained with PLASIMO using the 4-species RKM (reaction kinetic model). The data contains  the density and mean energy of electrons as well as the density of heavy-particle species in stationary state of the DC  glow discharges in argon. Modelling was carried out for a constant voltage of 350\u202fV, with a gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 16: PLASIMO modelling results using 4-species RKM for DC case ","mimetype":"text\/csv","size":"433.47 KB","created":"Mon, 06\/08\/2026 - 10:24","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"cd1b62de-a468-4446-baf1-e76600f5b607","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_16_4specRKM_RF_MCPlas.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas using the 4-species RKM (reaction kinetic model). The data contains  period-averaged density and mean energy of electrons as well as the density of heavy-particle species in stationary state of the RF  glow discharges in argon. Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz . A gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK were also considered for the modelling.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 16: MCPlas modelling results using 4-species RKM for RF case","mimetype":"text\/csv","size":"82.65 KB","created":"Mon, 06\/08\/2026 - 10:25","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"79d0ab73-5f39-4ee5-816e-c82846447ff4","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_16_4specRKM_RF_FEDM.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas using the 4-species RKM (reaction kinetic model). The data contains  period-averaged density and mean energy of electrons as well as the density of heavy-particle species in stationary state of the RF  glow discharges in argon. Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz . A gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK were also considered for the modelling.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 16: FEDM modelling results using 4-species RKM for RF case","mimetype":"text\/csv","size":"47.01 KB","created":"Mon, 06\/08\/2026 - 10:35","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"634760bd-7bf6-4a7f-af4c-04202239accd","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_16_4specRKM_RF_PLASIMO.csv","description":"\u003Cp\u003EModelling results obtained with PLASIMO using the 4-species RKM (reaction kinetic model). The data contains  period-averaged density and mean energy of electrons as well as the density of heavy-particle species in stationary state of the RF  glow discharges in argon. Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz . A gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK were also considered for the modelling.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 16: PLASIMO modelling results using 4-species RKM for RF case","mimetype":"text\/csv","size":"418.67 KB","created":"Mon, 06\/08\/2026 - 10:37","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"2da2dd31-1fa5-41d2-bac8-124da5950337","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_17_23specRKM_DC_MCPlas.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas using the 23-species RKM (reaction kinetic model). The data contains  the densities of charged and neutral  species in stationary state of the DC  glow discharges in argon. 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Modelling was carried out for a constant voltage of 350\u202fV, with a gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 17: FEDM modelling results using 23-species RKM for DC case","mimetype":"text\/csv","size":"95.94 KB","created":"Mon, 06\/08\/2026 - 10:47","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"1e7d5fb8-4476-4fa0-96b8-c39f81b42f37","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_17_23specRKM_DC_PLASIMO.csv","description":"\u003Cp\u003EModelling results obtained with PLASIMO using the 23-species RKM (reaction kinetic model). The data contains  the densities of charged and neutral  species in stationary state of the DC  glow discharges in argon. Modelling was carried out for a constant voltage of 350\u202fV, with a gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 17: PLASIMO modelling results using 23-species RKM for DC case","mimetype":"text\/csv","size":"1.58 MB","created":"Mon, 06\/08\/2026 - 10:48","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"f680d73b-04ea-468f-973b-2d444d7d8f3c","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_17_23specRKM_RF_MCPlas.csv","description":"\u003Cp\u003EModelling results obtained with MCPlas using the 23-species RKM (reaction kinetic model). The data contains the period-averaged densities of charged and neutral species in stationary state of the RF glow discharges in argon. Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz. 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Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz. A gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK were also considered for the modelling.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 17: FEDM modelling results using 23-species RKM for RF case","mimetype":"text\/csv","size":"93.96 KB","created":"Mon, 06\/08\/2026 - 10:52","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"a8ef10c5-ebba-4101-b942-1ccfb994b3a9","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Figure_17_23specRKM_RF_PLASIMO.csv","description":"\u003Cp\u003EModelling results obtained with PLASIMO using the 23-species RKM (reaction kinetic model). The data contains the period-averaged densities of charged and neutral species in stationary state of the RF glow discharges in argon. Modelling was carried out using a sinusoidal voltage with an amplitude of 350 V and a frequency of 13.56 MHz. A gap distance of 1\u202fcm, a gas pressure of 1\u202fTorr and a gas temperature of 300\u202fK were also considered for the modelling.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - Figure 17: PLASIMO modelling results using 23-species RKM for RF case","mimetype":"text\/csv","size":"801.61 KB","created":"Mon, 06\/08\/2026 - 10:54","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"86325868-ddcd-4e49-b035-624c97858abc","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_General_JSON_schema.json","description":"\u003Cp\u003EGeneral input data defining the setup are required to build the model via MCPlas toolbox. These general input data are provided in the JSON format and include \u0022plasma source\u0022, \u0022plasma medium\u0022 and \u0022diagnostics method\u0022 fields. The \u0022plasma source\u0022 describes the geometry, electrical, and material properties of the source. The \u0022plasma medium\u0022 encompasses the general characteristics of the gas under study, as well as the surface properties specific to the included species and surface materials. The \u0022diagnostics method\u0022 contains the relevant properties of the fluid-Poisson model, which is employed here as a diagnostic tool for investigation.  The provided JSON schema can generate input JSON data  via Adamant tool.\u003C\/p\u003E\n","format":"json","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - JSON schema for general input data","mimetype":"application\/json","size":"27.73 KB","created":"Tue, 06\/09\/2026 - 20:58","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"2cbf4f07-06da-449a-a052-58965cdd9a06","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Ar_Becker_2009.json","description":"\u003Cp\u003EMCPlas uses a standardised JSON format to define considered reaction kinetic model (RKM). The provided JSON file defines 4-species argon RKM used for calculations presented in the manuscript.\u003C\/p\u003E\n","format":"json","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - JSON file with 4-species reaction kinetic model data","mimetype":"application\/json","size":"265.9 KB","created":"Tue, 06\/09\/2026 - 21:16","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"037ee0c4-5c23-4b40-8ac2-ffdde5873439","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_Ar_Stankov_2022.json","description":"\u003Cp\u003EMCPlas uses a standardised JSON format to define considered reaction kinetic model (RKM). The provided JSON file defines 23-species argon RKM used for calculations presented in the manuscript.\u003C\/p\u003E\n","format":"json","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - JSON file with 23-species reaction kinetic model data","mimetype":"application\/json","size":"6.11 MB","created":"Tue, 06\/09\/2026 - 21:18","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"6d7b58b5-29ae-4b5b-a55c-17820a2774fb","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_General_input_data_4spec_0.json","description":"\u003Cp\u003EThis file defines the general input data for generating the COMSOL model via the MCPlas toolbox for the DC argon discharge case using the 4-species RKM and DDAn drift-diffusion approximation  described in the manuscript. For the RF case, the file is identical except that the voltage signal frequency must also be specified. Using the DDAc or DDA53 drift-diffusion approximation only requires replacing the DDAn specification in the file with the corresponding one.\u003C\/p\u003E\n","format":"json","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - JSON general input file for 4-species argon plasma modelling","mimetype":"application\/json","size":"2.55 KB","created":"Fri, 06\/12\/2026 - 23:29","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"},{"id":"702ef84f-830d-49db-b452-0c9e2fba3fc3","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1033_General_input_data_23spec.json","description":"\u003Cp\u003EThis file defines the general input data for generating the COMSOL model via the MCPlas toolbox for the DC argon discharge case using the 23-species RKM and DDAn drift-diffusion approximation  described in the manuscript. For the RF case, the file is identical except that the voltage signal frequency must also be specified. Using the DDAc or DDA53 drift-diffusion approximation only requires replacing the DDAn specification in the file with the corresponding one.\u003C\/p\u003E\n","format":"json","state":"Active","revision_timestamp":"Mon, 06\/15\/2026 - 00:00","name":"MCPlas, a MATLAB toolbox for reproducible plasma modelling - JSON general input file for 23-species argon plasma modelling","mimetype":"application\/json","size":"7.11 KB","created":"Fri, 06\/12\/2026 - 23:41","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Mon, 06\/15\/2026 - 00:00"}],"tags":[{"id":"02b8f23a-74ae-4f62-a99a-5d138f796aea","vocabulary_id":"2","name":"basic research"},{"id":"95452d90-ed0c-41cc-a020-93759a51d243","vocabulary_id":"2","name":"fluid modelling"},{"id":"bd1b5a52-45b9-4b8f-962d-791400aeeb09","vocabulary_id":"2","name":"Comsol"},{"id":"12af2a65-bb29-4943-a65e-c92fcd16d642","vocabulary_id":"2","name":"reproducibility"},{"id":"6d6f95cf-6896-48d5-88a0-6fb5a5ebfbb4","vocabulary_id":"2","name":"benchmark data"}],"groups":[{"description":"\u003Cp\u003E\u003Cstrong\u003ELeibniz Institute for Plasma Science and Technology\u003C\/strong\u003E\u003Cbr \/\u003E\nFelix-Hausdorff-Str. 2\u003Cbr \/\u003E\n17489 Greifswald\u003Cbr \/\u003E\nGERMANY\u003C\/p\u003E\n\u003Cp\u003E\u003Ca href=\u0022https:\/\/www.inp-greifswald.de\/en\/\u0022\u003Ehttps:\/\/www.inp-greifswald.de\/en\/\u003C\/a\u003E\u003Cbr \/\u003E\n\u003Cspan class=\u0022spamspan\u0022\u003E\u003Cspan class=\u0022u\u0022\u003Ewelcome\u003C\/span\u003E\u003Cimg class=\u0022spam-span-image\u0022 alt=\u0022at\u0022 width=\u002210\u0022 src=\u0022\/sites\/all\/modules\/spamspan\/image.gif\u0022 \/\u003E\u003Cspan class=\u0022d\u0022\u003Einp-greifswald\u003Cspan class=\u0022t\u0022\u003E [punkt] \u003C\/span\u003Ede\u003C\/span\u003E\u003C\/span\u003E\u003C\/p\u003E\n\u003Cp align=\u0022justify\u0022\u003EThe Leibniz Institute for Plasma Science and Technology (INP) is the largest non-university institute in the field of low temperature plasmas, their basics and technical applications in Europe. 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