{"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":"d8420686-6b4f-40b9-b02d-2e13b4e3c08a","name":"framework-unified-nonequilibrium-plasma-model-and-collisional-radiative-model","title":"Framework of unified nonequilibrium plasma model and collisional-radiative model for characterisation of microdischarges in metal vapours of Cd and Zn - dataset","author":"DO NOT USE","author_email":"baeva@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 provides the data related to the modelling of microdischarges in metal vapour of cadmium and zinc. The characterisation of the microdischarges was done in a framework that combined a unified nonequilibrium plasma model and a collisional-radiative model. The plasma model provided the basic plasma parameters (number densities of ground state neutral and singly charged species and their energies, electric field, discharge voltage). Number densities of excited atomic states were obtained on a second stage employing a collisional-radiative model and the already known plasma parameters. This modelling framework allowed one to obtain spatially and temporally resolved plasma parameters and the population of the excited atomic states in the entire discharge gap during the separation of the electric contacts. The modelling work was supported by electrical measurements, high-speed imaging and optical emission spectroscopy. The experimental findings enabled the calibration of the plasma model with respect to the discharge voltage and a qualitative and to some extent quantitative comparison of computed and measured spectral intensities.\u003C\/p\u003E\n","url":"https:\/\/www.inptdat.de\/dataset\/framework-unified-nonequilibrium-plasma-model-and-collisional-radiative-model","state":"Active","log_message":"Update to resource Framework of unified nonequilibrium plasma model and collisional-radiative model - Temporal evolution of the spatially averaged line intensities in Zn (figure 9b)","private":true,"revision_timestamp":"Wed, 05\/27\/2026 - 23:02","metadata_created":"Wed, 05\/27\/2026 - 01:00","metadata_modified":"Wed, 05\/27\/2026 - 23:02","creator_user_id":"5fc9da86-6527-478f-8b65-772400f5b81e","type":"Dataset","resources":[{"id":"58bfbabc-deea-48c6-b714-42a11f455736","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_1.csv","description":"\u003Cp\u003EIonisation rate coefficients Kion,t [m^3\/s] for Cd and Zn as a function of the electron temperature Te [eV]. The ionisation rate coefficients account for both direct and step-wise ionisation.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Wed, 05\/27\/2026 - 23:02","name":"Framework of unified nonequilibrium plasma model and collisional-radiative model - Ionisation rate coefficients (figure 1)","mimetype":"text\/csv","size":"390.36 KB","created":"Wed, 05\/27\/2026 - 17:47","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Wed, 05\/27\/2026 - 23:02"},{"id":"98ea36d5-ee8d-4ed2-8274-cf35531749c1","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_2a_0.csv","description":"\u003Cp\u003EThermo-field emission current density of electrons jtf [A\/m^2] from a cathode made of Cd as a function of the electric field E [V\/m] for various surface temperatures. The emission current density of electrons jtf is computed by means of the Transferred Matrix Method for various values of the electric field E and temperature of the cathode surface.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Wed, 05\/27\/2026 - 23:02","name":"Framework of unified nonequilibrium plasma model and collisional-radiative model - Thermo-field emission current density of electrons  from a cathode made of Cd (figure 2a)","mimetype":"text\/csv","size":"1.14 KB","created":"Wed, 05\/27\/2026 - 18:17","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Wed, 05\/27\/2026 - 23:02"},{"id":"4739c11b-25a4-4030-bf9d-694c9b961322","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_2b_0.csv","description":"\u003Cp\u003EThermo-field emission current density of electrons jtf [A\/m^2] from a cathode made of Zn as a function of the electric field E [V\/m] for various surface temperatures. The emission current density of electrons jtf is computed by means of the Transferred Matrix Method for various values of the electric field E and temperature of the cathode surface.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Wed, 05\/27\/2026 - 23:02","name":"Framework of unified nonequilibrium plasma model and collisional-radiative model - Thermo-field emission current density of electrons from a cathode made of Zn (figure 2b)","mimetype":"text\/csv","size":"766 bytes","created":"Wed, 05\/27\/2026 - 18:34","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Wed, 05\/27\/2026 - 23:02"},{"id":"614e1e21-ab92-456f-ba1c-a1d7f98efbae","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_4a_1.csv","description":"\u003Cp\u003EMeasured and computed in the UNEM voltage for microdischarges with gap lengths of 60, 100, and 160 \u03bcm in metal vapours of Cd. The experimental value are provided for a series of measurements with gap lengths around 60, 100, 160 \u00b5m, while the computed voltage is a single value for the corresponding gap length.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Wed, 05\/27\/2026 - 23:02","name":"Framework of unified nonequilibrium plasma model and collisional-radiative model - Measured and computed in the UNEM voltage for microdischarges in metal vapours of Cd (figure 4a)","mimetype":"text\/csv","size":"1.4 KB","created":"Wed, 05\/27\/2026 - 19:08","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Wed, 05\/27\/2026 - 23:02"},{"id":"c88f27aa-18d9-4cba-b2aa-2e535cc078b9","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_4b_0.csv","description":"\u003Cp\u003EMeasured and computed in the UNEM voltage for microdischarges with gap lengths of 60, 100, and 160 \u03bcm in metal vapours of Zn. The experimental values are provided for a series of measurements with gap lengths around 60, 100, 160 \u00b5m, while the computed voltage is a single value for the corresponding gap length.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Wed, 05\/27\/2026 - 23:02","name":"Framework of unified nonequilibrium plasma model and collisional-radiative model - Measured and computed in the UNEM voltage for microdischarges in metal vapours of Zn (figure 4b)","mimetype":"text\/csv","size":"2.92 KB","created":"Wed, 05\/27\/2026 - 19:20","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Wed, 05\/27\/2026 - 23:02"},{"id":"01a1a092-4c0d-49f7-9aaf-34e50d9334f8","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_5_Cd.csv","description":"\u003Cp\u003EDistributions of the electric potential for microdischarges with gap lengths of 60, 100, and 160 \u03bcm in metal vapours of Cd. The spatial distribution (distance z in meters) of the electric potential (volts) in microdischarges in metal vapours of Cd is shown for gap lengths of 60, 100 and 160 \u00b5m.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Wed, 05\/27\/2026 - 23:02","name":"Framework of unified nonequilibrium plasma model and collisional-radiative model - Distributions of the electric potential for microdischarges in metal vapours of Cd (figure 5 Cd)","mimetype":"text\/csv","size":"160.37 KB","created":"Wed, 05\/27\/2026 - 19:35","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Wed, 05\/27\/2026 - 23:02"},{"id":"4fdc229f-336e-499f-8f3b-e7de4ad17e42","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_5_Zn.csv","description":"\u003Cp\u003EDistributions of the electric potential for microdischarges with gap lengths of 60, 100, and 160 \u03bcm in metal vapours of Zn. The spatial distribution (distance z in meters) of the electric potential (in volts) in microdischarges in metal vapours of Zn is shown for gap lengths of 60, 100 and 160 \u00b5m.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Wed, 05\/27\/2026 - 23:02","name":"Framework of unified nonequilibrium plasma model and collisional-radiative model - Distributions of the electric potential for microdischarges in metal vapours of Zn (figure 5 Zn)","mimetype":"text\/csv","size":"327.08 KB","created":"Wed, 05\/27\/2026 - 19:43","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Wed, 05\/27\/2026 - 23:02"},{"id":"dbf1c9bb-6eba-4676-bcc0-17b25af3c16e","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_6%20Cd.csv","description":"\u003Cp\u003ESpatial distribution of the space charge density in the cathode sheath of the microdischarge in Cd. The distribution is along the distance z in m, the space charge density rho_q  is in C\/m^3 .\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Wed, 05\/27\/2026 - 23:02","name":"Framework of unified nonequilibrium plasma model and collisional-radiative model - Density of space charge in the vicinity of the cathode in microdischarges of Cd (figure 6 Cd)","mimetype":"text\/csv","size":"13.52 KB","created":"Wed, 05\/27\/2026 - 19:52","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Wed, 05\/27\/2026 - 23:02"},{"id":"45dd45d3-6703-44ea-9c01-91237112d5fa","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_6%20Zn.csv","description":"\u003Cp\u003ESpatial distribution of the space charge density in the cathode sheath of the microdischarge in Zn. The distribution is along the distance z in m, the space charge density rho_q  is in C\/m^3 .\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Wed, 05\/27\/2026 - 23:02","name":"Framework of unified nonequilibrium plasma model and collisional-radiative model - Density of space charge in the vicinity of the cathode in microdischarges of Zn (figure 6 Zn)","mimetype":"text\/csv","size":"47.26 KB","created":"Wed, 05\/27\/2026 - 19:59","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Wed, 05\/27\/2026 - 23:02"},{"id":"49ab0148-c1e5-4dc7-8093-bf117cec051b","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_7a.csv","description":"\u003Cp\u003EDistribution of the electron temperature Te in microdischages of metal vapour of Cd and Zn for a gap length of 60 \u03bcm.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Wed, 05\/27\/2026 - 23:02","name":"Framework of unified nonequilibrium plasma model and collisional-radiative model - Distribution of the electron temperature in microdischages of metal vapour of Cd and Zn (figure 7a)","mimetype":"text\/csv","size":"166.46 KB","created":"Wed, 05\/27\/2026 - 20:08","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Wed, 05\/27\/2026 - 23:02"},{"id":"8f802cf4-5612-448c-961a-531f6278e2ee","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_7b.csv","description":"\u003Cp\u003EDistributions of the gas temperature T in microdischages of metal vapour of Cd and Zn for a gap length of 60 \u03bcm.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Wed, 05\/27\/2026 - 23:02","name":"Framework of unified nonequilibrium plasma model and collisional-radiative model - Distributions of the gas temperature in microdischages of metal vapour of Cd and Zn (figure 7b)","mimetype":"text\/csv","size":"162.25 KB","created":"Wed, 05\/27\/2026 - 20:10","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Wed, 05\/27\/2026 - 23:02"},{"id":"424b8078-6765-4be2-98b1-3261ab9d1c29","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_8.csv","description":"\u003Cp\u003EPredicted number densities of electrons and excited states of Cd and Zn for a gap length of 160 \u03bcm.\u003C\/p\u003E\n","format":"csv","state":"Active","revision_timestamp":"Wed, 05\/27\/2026 - 23:02","name":"Framework of unified nonequilibrium plasma model and collisional-radiative model - Predicted number densities of electrons and excited states of Cd and Zn (figure 8)","mimetype":"text\/csv","size":"330.02 KB","created":"Wed, 05\/27\/2026 - 20:12","resource_group_id":"8213480c-adb6-4936-8811-f1dd8f8b3a2f","last_modified":"Date changed  Wed, 05\/27\/2026 - 23:02"},{"id":"f31a006b-25d4-4e5e-9e14-153972ea1595","revision_id":"","url":"https:\/\/www.inptdat.de\/system\/files\/node1030_figure_9a.csv","description":"\u003Cp\u003ETemporal evolution of the spatially averaged line intensities Iqp(\u03bb, t) in Cd . 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