2.3.2 spase://NASA/NumericalData/Wind/EPACT/STEP/Directional/DifferentialFlux/CNO/PT10M Wind Energetic Particle Acceleration Composition Transport (EPACT) SupraThermal Energetic Particle Telescope (STEP) Differential, Directional Carbon, Nitrogen, and Oxygen Fluxes, 10 min Data https://doi.org/10.48322/0y67-vc97 2021-05-31T12:34:56.789 2021-05-31T12:34:56.789 Updated to SPASE Version 2.3.2 if needed, Applied quality control for DOI usage, LFB The EPACT Instrument on Wind STEP - SupraThermal Energetic Particle Telescope measures Ion Fluxes of Protons (H) in 0.12.5 MeV Energy Range and He-Fe Nuclei in the ~0.032 MeV/nucleon Energy Ranges in two identical Telescopes, each with a Geometrical Factor of 0.4 cm^2 sr and a rectangular Field of View with an Angular Acceptance of 44° in Azimuth and 17° in Polar Angle. Mihir Desai Mihir, Desai; Mukherjee, Joey; & Filwett, Rachael J. 2021-01-01T00:00:00 NASA Space Physics Data Facility spase://SMWG/Person/Mihir.Desai PrincipalInvestigator spase://SMWG/Person/Robert.E.McGuire MetadataContact spase://SMWG/Person/Lee.Frost.Bargatze MetadataContact Wind Project Web Site - Comprehensive Solar Wind Laboratory for Long-Term Solar Wind Observations https://wind.nasa.gov/ Wind Project Web Site spase://VSPO/NumericalData/Wind/EPACT/STEP/Directional/DifferentialFlux/CNO/PT10M spase://SMWG/Repository/NASA/GSFC/SPDF Online Open FTPS from SPDF (not with most browsers) ftps://spdf.gsfc.nasa.gov/pub/data/wind/epact/step/directional-diff-cno-flux-10min/ Access to Data in CDF Format via ftp from SPDF HTTPS from SPDF https://spdf.gsfc.nasa.gov/pub/data/wind/epact/step/directional-diff-cno-flux-10min/ Access to Data in CDF Format via http from SPDF CDAWeb https://cdaweb.gsfc.nasa.gov/index.html/ WI_EPACT_STEP-DIRECTIONAL-DIFF-CNO-FLUX-10MIN Access to ASCII, CDF, and Plots via NASA/GSFC CDAWeb CDF None Mihir Desai. Please acknowledge the Data Providers and CDAWeb when using these Data. spase://SMWG/Repository/NASA/GSFC/SPDF Online Open CDAWeb HAPI Server https://cdaweb.gsfc.nasa.gov/hapi WI_EPACT_STEP-DIRECTIONAL-DIFF-CNO-FLUX-10MIN Web Service to this product using the HAPI interface. CSV Mihir Desai. Please acknowledge the Data Providers and CDAWeb when using these Data. Calibrated spase://SMWG/Instrument/Wind/EPACT EnergeticParticles Ephemeris MagneticField ThermalPlasma 1994-11-21T00:00:00.000 2017-12-31T23:58:32.000 PT10M Heliosphere Heliosphere.Inner Heliosphere.NearEarth Epoch Time Epoch Epoch Time, Beginning of Interval Average Type: standard This parameter exhibits an increasing monotonic progression. PT10M ms 1.0e-3>s Epoch E14.8 6.2951018619904e+13 6.3745034619904e+13 LinearScale 03-Nov-1994 00:00:00.000 01-Jan-2020 00:00:00.000 -9.99e+32 Temporal CNO Energy, Minimum Time series defined by using: EPOCH energy_min Carbon, Nitrogen, Oxygen Energy, Minimum Column 1 Labels from CNO_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg"] Column 2 Labels from TELESCOPE_INDEX: [1, 2] PT10M MeV/n 1.602176565e-13>J/n CNO_energy_min E12.5 7 2 -9.99e+32 Ion Minimum Energy CNO Energy, Center Time series defined by using: EPOCH energy_center Carbon, Nitrogen, Oxygen Energy, Center Column 1 Labels from CNO_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg"] Column 2 Labels from TELESCOPE_INDEX: [1, 2] PT10M MeV/n 1.602176565e-13>J/n CNO_energy_center E12.5 7 2 -9.99e+32 Ion Energy CNO Energy, Maximum Time series defined by using: EPOCH energy_max Carbon, Nitrogen, Oxygen Energy, Maximum Column 1 Labels from CNO_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg"] Column 2 Labels from TELESCOPE_INDEX: [1, 2] PT10M MeV/n 1.602176565e-13>J/n CNO_energy_max E12.5 7 2 -9.99e+32 Ion Maximum Energy CNO Energy Efficiency, Low Time series defined by using: EPOCH energy_efficiency_low Carbon, Nitrogen, Oxygen Efficiency, Low Column 1 Labels from CNO_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg"] Column 2 Labels from TELESCOPE_INDEX: [1, 2] PT10M MeV/n 1.602176565e-13>J/n CNO_energy_efficiency_low E12.5 7 2 -9.99e+32 Ion Minimum Energy CNO Energy Efficiency, High Time series defined by using: EPOCH energy_efficiency_high Carbon, Nitrogen, Oxygen Efficiency, High Column 1 Labels from CNO_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg"] Column 2 Labels from TELESCOPE_INDEX: [1, 2] PT10M MeV/n 1.602176565e-13>J/n CNO_energy_efficiency_high E12.5 7 2 -9.99e+32 Ion Maximum Energy CNO Energy Efficiency, Average Time series defined by using: EPOCH energy_efficiency_avg Carbon, Nitrogen, Oxygen Energy Efficiency, Average Column 1 Labels from CNO_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg"] Column 2 Labels from TELESCOPE_INDEX: [1, 2] PT10M MeV/n 1.602176565e-13>J/n CNO_energy_efficiency_avg E12.5 7 2 -9.99e+32 Ion Average Energy CNO Energy, Center, Telescope 1 Time series defined by using: EPOCH ENERGY_CENTER_T1 Carbon, Nitrogen, Oxygen Energy, Center, Telescope 1 This parameter is virtual. It is calculated by calling the function ARR_SLICE with the following input parameters: energy_center. PT10M MeV/n 1.602176565e-13>J/n CNO_energy_center E12.5 7 Element 1 1 1 Element 2 2 2 Element 3 3 3 Element 4 4 4 Element 5 5 5 Element 6 6 6 Element 7 7 7 0.0 100000.0 -9.99e+32 Ion Energy CNO Energy, Center, Telescope 2 Time series defined by using: EPOCH ENERGY_CENTER_T2 Carbon, Nitrogen, Oxygen Energy, Center, Telescope 2 This parameter is virtual. It is calculated by calling the function ARR_SLICE with the following input parameters: energy_center. PT10M MeV/n 1.602176565e-13>J/n CNO_energy_center E12.5 7 Element 1 1 1 Element 2 2 2 Element 3 3 3 Element 4 4 4 Element 5 5 5 Element 6 6 6 Element 7 7 7 0.0 100000.0 -9.99e+32 Ion Energy CNO Flux Time series defined by using: EPOCH flux Carbon, Nitrogen, Oxygen Flux Column 1 Labels from SECTOR_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg","Sector 8 x deg"] Column 2 Labels from CNO_INDEX: ["CNO energy center 2","CNO energy center 3","CNO energy center 4","CNO energy center 5","CNO energy center 6","CNO energy center 7","CNO energy center 7"] Column 3 Labels from CNO_INDEX: [1, 2] PT10M (cm^2 s sr MeV/n)^-1 6.24161e-19>(m^2 s sr J/n)^-1 CNO_flux E12.5 8 7 2 -9.99e+32 Ion Differential NumberFlux CNO Flux Uncertainty, Sigma Time series defined by using: EPOCH flux_sigma Carbon, Nitrogen, Oxygen Flux Uncertainty, Sigma Column 1 Labels from SECTOR_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg","Sector 8 x deg"] Column 2 Labels from CNO_INDEX: ["CNO energy center 2","CNO energy center 3","CNO energy center 4","CNO energy center 5","CNO energy center 6","CNO energy center 7","CNO energy center 7"] Column 3 Labels from CNO_INDEX: [1, 2] PT10M (cm^2 s sr MeV/n)^-1 6.24161e-19>(m^2 s sr J/n)^-1 CNO_flux_sigma E12.5 8 7 2 -9.99e+32 Ion Differential Uncertainty NumberFlux CNO Flux, Telescope 1, Energy versus Pitch Angle Time series defined by using: EPOCH FLUX_T1 Carbon, Nitrogen, Oxygen Flux, Telescope 1, Energy versus Pitch Angle Displays Column 1 Labels from SECTOR_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg","Sector 8 x deg"] Column 2 Labels from CNO_INDEX: ["CNO energy center 2","CNO energy center 3","CNO energy center 4","CNO energy center 5","CNO energy center 6","CNO energy center 7","CNO energy center 7"] This parameter is virtual. It is calculated by calling the function ARR_SLICE with the following input parameters: flux. PT10M (cm^2 s sr MeV/n)^-1 6.24161e-19>(m^2 s sr J/n)^-1 CNO_flux E12.5 8 7 -9.99e+32 Ion Differential NumberFlux CNO Flux, Telescope 2, Energy versus Pitch Angle Time series defined by using: EPOCH FLUX_T2 Carbon, Nitrogen, Oxygen Flux, Telescope 2, Energy versus Pitch Angle Displays Column 1 Labels from SECTOR_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg","Sector 8 x deg"] Column 2 Labels from CNO_INDEX: ["CNO energy center 2","CNO energy center 3","CNO energy center 4","CNO energy center 5","CNO energy center 6","CNO energy center 7","CNO energy center 7"] This parameter is virtual. It is calculated by calling the function ARR_SLICE with the following input parameters: flux. PT10M (cm^2 s sr MeV/n)^-1 6.24161e-19>(m^2 s sr J/n)^-1 CNO_flux E12.5 8 7 -9.99e+32 Ion Differential NumberFlux CNO Flux, Telescope 1, Spectrograms by Energy Time series defined by using: EPOCH flux_t1_byE_atA Carbon, Nitrogen, Oxygen Flux, Telescope 1, 8 Pitch Angles as Spectrograms by Energy Column 1 Labels from SECTOR_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg","Sector 8 x deg"] Column 2 Labels from CNO_INDEX: ["CNO energy center 2","CNO energy center 3","CNO energy center 4","CNO energy center 5","CNO energy center 6","CNO energy center 7","CNO energy center 7"] This parameter is virtual. It is calculated by calling the function ALTERNATE_VIEW with the following input parameters: FLUX_T1. PT10M (cm^2 s sr MeV/n)^-1 6.24161e-19>(m^2 s sr J/n)^-1 Spectrogram CNO_flux E12.5 8 7 -9.99e+32 Ion Differential NumberFlux CNO Flux, Telescope 2, Spectrograms by Energy Time series defined by using: EPOCH flux_t2_byE_atA Carbon, Nitrogen, Oxygen Flux, Telescope 2, 8 Pitch Angles as Spectrograms by Energy Column 1 Labels from SECTOR_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg","Sector 8 x deg"] Column 2 Labels from CNO_INDEX: ["CNO energy center 2","CNO energy center 3","CNO energy center 4","CNO energy center 5","CNO energy center 6","CNO energy center 7","CNO energy center 7"] This parameter is virtual. It is calculated by calling the function ALTERNATE_VIEW with the following input parameters: FLUX_T2. PT10M (cm^2 s sr MeV/n)^-1 6.24161e-19>(m^2 s sr J/n)^-1 Spectrogram CNO_flux E12.5 8 7 -9.99e+32 Ion Differential NumberFlux CNO Flux, Telescope 1, Spectrograms by Pitch Angle Time series defined by using: EPOCH flux_t1_byA_atE Carbon, Nitrogen, Oxygen Flux, Telescope 1, 7 Energies as Spectrograms by Pitch Angle Column 1 Labels from SECTOR_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg","Sector 8 x deg"] Column 2 Labels from CNO_INDEX: ["CNO energy center 2","CNO energy center 3","CNO energy center 4","CNO energy center 5","CNO energy center 6","CNO energy center 7","CNO energy center 7"] This parameter is virtual. It is calculated by calling the function ALTERNATE_VIEW with the following input parameters: FLUX_T1. PT10M (cm^2 s sr MeV/n)^-1 6.24161e-19>(m^2 s sr J/n)^-1 Spectrogram CNO_flux E12.5 8 7 -9.99e+32 Ion Differential NumberFlux CNO Flux, Telescope 2, Spectrograms by Pitch Angle Time series defined by using: EPOCH flux_t2_byA_atE Carbon, Nitrogen, Oxygen Flux, Telescope 2, 7 Energies as Spectrograms by Pitch Angle Column 1 Labels from SECTOR_INDEX: ["Sector 2 x deg","Sector 3 x deg","Sector 4 x deg","Sector 5 x deg","Sector 6 x deg","Sector 7 x deg","Sector 8 x deg","Sector 8 x deg"] Column 2 Labels from CNO_INDEX: ["CNO energy center 2","CNO energy center 3","CNO energy center 4","CNO energy center 5","CNO energy center 6","CNO energy center 7","CNO energy center 7"] This parameter is virtual. It is calculated by calling the function ALTERNATE_VIEW with the following input parameters: FLUX_T2. PT10M (cm^2 s sr MeV/n)^-1 6.24161e-19>(m^2 s sr J/n)^-1 Spectrogram CNO_flux E12.5 8 7 -9.99e+32 Ion Differential NumberFlux CNO Index Time series defined by using: EPOCH CNO_index Carbon, Nitrogen, Oxygen Index PT10M I2 LinearScale 7 1 7 -9 Other Sector Index Time series defined by using: EPOCH SECTOR_index Sector Index PT10M sector index Sector Index I2 LinearScale 8 1 8 -9 Other Telescope Index Time series defined by using: EPOCH TELESCOPE_index Telescope Index PT10M I2 LinearScale 2 1 2 -9 Other Magnetic Field, Magnitude Time series defined by using: EPOCH B Magnetic Field, Magnitude PT10M nT 1.0e-9>T B E12.5 2 B Telescope 1 1 1 B Telescope 2 2 2 -1000.0 1000.0 -9.99e+32 Magnitude Magnetic Magnetic Field, Theta Angle Time series defined by using: EPOCH Btheta Magnetic Field, Theta Angle PT10M ° 0.0174532925>rad Spherical GSE Btheta E12.5 2 Element 1 1 1 Element 2 2 2 -90.0 90.0 -9.99e+32 DirectionAngle.PolarAngle Magnetic Magnetic Field, Phi Angle Time series defined by using: EPOCH Bphi Magnetic Field, Phi Angle PT10M ° 0.0174532925>rad Spherical GSE Bphi E12.5 2 Bphi Telescope 1 1 1 Bphi Telescope 2 2 2 0.0 360.0 -9.99e+32 DirectionAngle.AzimuthAngle Magnetic Magnetic Field, RMS Time series defined by using: EPOCH Brms Magnetic Field, Root Mean Square (RMS) PT10M nT 1.0e-9>T Brms E12.5 2 Brms Telescope 1 1 1 Brms Telescope 2 2 2 0.0 1000.0 -9.99e+32 Variance Magnetic Spacecraft Radial Distance Time series defined by using: EPOCH R Spacecraft Radial Distance PT10M Re 6.3712e6>m R E12.5 2 R Telescope 1 1 1 R Telescope 2 2 2 0.0 300.0 -9.99e+32 Magnitude Positional Spacecraft Position, GSE Cartesian Coordinates Time series defined by using: EPOCH xyzGSE Spacecraft Position, Geocentric Solar Ecliptic, GSE, Cartesian Coordinates Column 1 Labels from TELESCOPE_INDEX: [x (GSE),y (GSE),z (GSE)] Column 2 Labels from TELESCOPE_INDEX: [1, 2] PT10M Re 6.3712e6>m Cartesian GSE XYZ GSE E12.5 3 2 -9.99e+32 Vector Positional XYZ GSE, Telescope 1 Time series defined by using: EPOCH xyzGSE_T1 XYZ GSE, Telescope 1 This parameter is virtual. It is calculated by calling the function ARR_SLICE with the following input parameters: xyzGSE. PT10M Re 6.3712e6>m Cartesian GSE TimeSeries XYZ GSE Telescope 1 E12.5 3 Element 1 1 x (GSE) Element 2 2 y (GSE) Element 3 3 z (GSE) -300.0 300.0 -9.99e+32 Vector Positional XYZ GSE, Telescope 2 Time series defined by using: EPOCH xyzGSE_T2 XYZ GSE, Telescope 2 This parameter is virtual. It is calculated by calling the function ARR_SLICE with the following input parameters: xyzGSE. PT10M Re 6.3712e6>m Cartesian GSE TimeSeries XYZ GSE Telescope 2 E12.5 3 Element 1 1 x (GSE) Element 2 2 y (GSE) Element 3 3 z (GSE) -300.0 300.0 -9.99e+32 Vector Positional Solar Wind Velocity Time series defined by using: EPOCH Vsw Solar Wind Velocity, Vsw PT10M km/s 1.0e3>m/s Vsw E12.5 2 Vsw Telescope 1 1 1 Vsw Telescope 2 2 2 -3000.0 3000.0 -9.99e+32 Ion Magnitude Velocity Spacecraft Velocity, GSE Cartesian Coordinates Time series defined by using: EPOCH velocity Spacecraft Velocity, Geocentric Solar Ecliptic, GSE, Cartesian Coordinates Column 1 Labels from TELESCOPE_INDEX: [Vx,Vy,Vz] Column 2 Labels from TELESCOPE_INDEX: [1, 2] PT10M km/s 1.0e3>m/s Cartesian GSE Velocity E12.5 3 2 -9.99e+32 Vector Positional Velocity, Telescope 1 Time series defined by using: EPOCH velocity_T1 Velocity, Telescope 1 This parameter is virtual. It is calculated by calling the function ARR_SLICE with the following input parameters: velocity. PT10M km/s 1.0e3>m/s TimeSeries Velocity Telescope 1 E12.5 3 Element 1 1 Vx Element 2 2 Vy Element 3 3 Vz -10000.0 10000.0 -9.99e+32 Ion Velocity Velocity, Telescope 2 Time series defined by using: EPOCH velocity_T2 Velocity, Telescope 2 This parameter is virtual. It is calculated by calling the function ARR_SLICE with the following input parameters: velocity. PT10M km/s 1.0e3>m/s TimeSeries Velocity Telescope 2 E12.5 3 Element 1 1 Vx Element 2 2 Vy Element 3 3 Vz -10000.0 10000.0 -9.99e+32 Ion Velocity Proton Number Density Time series defined by using: EPOCH Np Proton Number Density PT10M cm^-3 1.0e6>m^-3 Np E12.5 2 Np Telescope 1 1 1 Np Telescope 2 2 2 0.0 10000.0 -9.99e+32 Proton Scalar NumberDensity 1