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SPASE version 2.0.1

Numerical Data Product: Geotail CPI Definitive Solar Wind Moments

Resource ID

spase://VMO/NumericalData/Geotail/CPI/SWA_PT48S

Name

Geotail CPI Definitive Solar Wind Moments

Description

The CPI Solar Wind analyzer definitive plasma moments. The CPI/SW data are good in the solar wind and may be usefull in the magnetosheath.

Additional information

CPI Survey Plots: Geotail CPI description and survey plots.

Contact

	Role	Person
1.	Principal investigator	Prof. Louis A. Frank
2.	Data producer	Dr. Kent L. Ackerson
3.	Metadata contact	Jan Merka

Release date

2009-07-15 22:15:10

Repository #1

Name

CDAWeb Data Repository FTP Interface

Availability

Online

Access rights

Open

URL

CDAWeb FTP download

Format

CDF

Encoding

None

Repository #2

Name

University of Iowa

Availability

Online

Access rights

Open

URL

University of Iowa: Geotail CPI SW data

Format

Text

Encoding

ASCII

Instrument

Geotail CPI

Measurement type

Ion composition

Thermal plasma

Temporal description

Start date: 1992-09-28 00:00:34
Relative stop date: 2 months ago
Cadence: 48 seconds

Observed regions

Earth.Magnetosheath

Heliosphere.NearEarth

Caveats

The CPI solar wind ion analyzer is an E/Q analyzer and the initial distribution functions were calculated assuming that the plasma is H+. Care must be taken when multi-component plasmas are present. If He++ is present and is flowing with the same speed as the H+ component, it will contribute to the distribution function at twice the velocity (four times the energy) of the H+. To facilitate the automated processing of the data the integral was evaluated between |vmin| = 171 km/s and |vmax| = 1.35 × |u|. The resulting temperatures produce excellent fits to the observations. When He++ is present the distribution functions are consistent with an He++ temperature, THe++ = 4 × TH+, i.e., the H+ and He++ have similar thermal velocities.

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Parameters

Parameter #1

Name: Time
Parameter key: Epoch
Description: Time in milliseconds, centered, since CDF Epoch
Units: ms
Conversion to SI units: 1e-3>s
Valid minimum: 08-Sep-1992 00:00:00.000
Valid maximum: 31-Dec-2020 20:00:00.000
Fill value: -1.0E31
Parameter type: Temporal

Parameter #2

Name

Vi GSE (r,theta,phi)

Parameter key

SW_V

Description

Ion bulk flow velocity vector in spherical GSE coordinates

Caveats

From 5 deg angular bins

Units

km/s

Conversion to SI units

1e3>m/s

Coordinate system

Spherical GSE

Rendering hints

Format: F9.2

Structure

Size

Elements

Index	Name	Units	Valid max	Fill value
1	Vr	km/s	1200.0	-1.0E31
2	Vtheta	deg	180.0	-1.0E31
3	Vphi	deg	360.0	-1.0E31

Particle type

Proton

AlphaParticle

Ion

Quantity

Flow velocity

Qualifier

Moment

Vector

Parameter #3

Name

Vi GSE

Parameter key

SW_Vc

Description

Ion bulk flow velocity vector in GSE cartesian coordinates

Caveats

From 5 deg angular bins

Units

km/s

Conversion to SI units

1e3>m/s

Coordinate system

Cartesian GSE

Rendering hints

Format: F7.0

Structure

Size

Elements

Index	Name	Valid min	Valid max	Fill value
1	Vx	-1400.0	1400.0	-1.0E31
2	Vy	-1400.0	1400.0	-1.0E31
3	Vz	-1400.0	1400.0	-1.0E31

Particle type

Proton

AlphaParticle

Ion

Quantity

Flow velocity

Qualifier

Moment

Vector

Parameter #4

Name

Parameter key

SW_T

Description

Kinetic temperature of hydrogen component of solar wind, scalar

Caveats

Calculated by integrating the distribution function

Units

Rendering hints

Format: F7.0

Valid minimum

10000.0

Valid maximum

1.0E7

Fill value

-1.0E31

Particle type

Proton

Quantity

Temperature

Qualifier

Moment

Scalar

Parameter #5

Name

Parameter key

SW_P_Den

Description

Ion number density (SWA), scalar

Caveats

Assuming no helium (0.3 - several hundred) if the density is less than 0.3/cc the higher moments (velocity, temperature) shall not be used because of the poor counting statistics.

Units

cm^-3

Conversion to SI units

1e6>m^-3

Rendering hints

Format: F8.3

Valid minimum

0.01

Valid maximum

1000.0

Fill value

-1.0E31

Particle type

Proton

Quantity

Number density

Qualifier

Moment

Scalar

Parameter #6

Name: Psw
Parameter key: SW_Pressure
Description: Ion pressure (assuming protons measured and adding 5% alphas, from SWA), scalar
Caveats: Assuming Vp = Va, P = C * Np * mp * Vp*Vp * [1 + 4(.05)]. mp = 1.67 * 10^(-27), C = 10^(21), Np in #/cc, Vp in km/s. Pressure not provided for density less than 0.3/cc because of the poor counting statistics.
Units: nPa
Conversion to SI units: 1e-9>Pa
Valid minimum: 1.0E-4
Valid maximum: 100.0
Fill value: -1.0E31
Particle type: Proton; AlphaParticle; Ion
Quantity: Pressure
Qualifier: Scalar

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SPASE version 2.0.0

Instrument: Geotail CPI

Instrument ID

spase://SMWG/Instrument/Geotail/CPI

Name

Geotail CPI

Alternate name

Geotail Comprehensive Plasma Instrumentation

Description

The objective of the Comprehensive Plasma Instrumentation (CPI) investigation is to make comprehensive observations of the three-dimensional velocity distribution functions of electrons and positive ions, with identification of ion species. The instrument contains three sets of quadrispherical analyzers with channel electron multipliers. These three obtain three-dimensional measurements for hot plasma and solar wind electrons, for solar wind ions, and for positive-ion composition measurements. The positive-ion composition measurement of the Ion Composition (IC) analyzer includes five miniature imaging mass spectrometers at the exit aperture of the analyzer, and covers masses from 1 to 550 u/Q at 100 eV, and 1 to 55 u/Q at 10 keV. The Hot Plasma (HP) analyzer measures electrons and ions in the range 1-50,000 eV/Q. The Solar Wind (SW) analyzer measures ions from 150 to 7,000 eV/Q. Sequencing of the energy analyzers and mass spectrometers, and other control functions, are provided by two microprocessors.

Additional information

NSSDC's Master Catalog: Information about the Comprehensive Plasma Instrument (CPI)

Contact

	Role	Person
1.	Principal investigator	Prof. Louis A. Frank

Release date

2009-05-20 21:10:15

Prior ID

spase://nssdc/instrument/1992-044A-04

Instrument type

Quadrispherical Analyser

Investigation name

CPI on GEOTAIL

Observatory

Geotail

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SPASE version 2.0.0

Observatory: Geotail

Observatory ID

spase://SMWG/Observatory/Geotail

Name

Geotail

Alternate name

1992-044A

GTL

ISTP/Geotail

GGS/Geotail

Geomagnetic Tail Lab

Description

The solar wind draws the Earth's magnetic field into a long tail on the nightside of the Earth and stores energy in the stretched field lines of the magnetotail. During active periods, the tail couples with the near-Earth magnetosphere, sometimes releasing energy stored in the tail and activating auroras in the polar ionosphere.

The Geotail mission measures global energy flow and transformation in the magnetotail to increase understanding of fundamental magnetospheric processes. This includes the physics of the magnetopause magnetospheric boundary regions, the lobe and plasma sheet, and reconnection and neutral line formation, i.e., the mechanisms processes of input, transport, storage, release and conversion of mass, momentum and energy in the magnetotail.

Geotail, together with Wind, Polar, SOHO, and Cluster projects, constitute a cooperative scientific satellite project designated the International Solar Terrestrial Physics (ISTP) program which aims at gaining improved understanding of the physics of solar-terrestrial relations.

Geotail is a spin-stabilized spacecraft utilizing mechanically despun antennas with a design lifetime of about four years. The nominal spin rate of the spacecraft is about 20 rpm around a spin axis maintained between 85-89 degrees to the ecliptic plane. Geotail is cylindrical, approximately 2.2 m in diameter, and 1.6 m high. with It has body-mounted solar cells. Geotail also has and a back-up battery subsystem which that operates when the spacecraft is in the Earth's shadow (limited to 2 hrs). Real-time telemetry data transmitted in X-band are received at the Usuda Deep Space Center (UDSC) in Japan. There are two tape recorders on board, each with a capacity of 450 Mb, which allows daily 24-hour data coverage and are collected in playback mode by the NASA Deep Space Network (DSN).

The Geotail mission is divided into two phases. During the two-year initial phase, the orbit apogee was kept on the nightside of the Earth by using the Moon's gravity in a series of double-lunar swing-by maneuvers that result in the spacecraft spending most of its time in the distant magnetotail (maximum apogee about 200 Earth radii) with a period varying from one to four months. Then, in November 1994, there were a series of maneuvers that reduced the apogee to 50 Re. After three more months in the magnetotail the spacecraft was put in a 10 by 30 Re orbit where it has remained except that the perigee was reduced from 10 to 9 Re in June 1997.

Details on the Geotail mission and instrumentation are given in the Journal of Geomagnetism and Geoelectricity (Vol. 46, No. 1, 1994); online from JGG at

http://www.terrapub.co.jp/journals/EPS/JGG

Additional information

NSSDC's Master Catalog: Information about the Geotail mission

Contact

	Role	Person
1.	Project scientist	Guan Le
2.	Project scientist	Prof. Masaki Fujimoto
3.	Metadata contact	Jan Merka

Release date

2009-05-20 20:00:12

Location

Region: Earth.Magnetosphere; Heliosphere.NearEarth

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Data Description

Table of Contents

Numerical Data Product: Geotail CPI Definitive Solar Wind Moments

Parameters

Parameter #1

Parameter #2

Parameter #3

Parameter #4

Parameter #5

Parameter #6

Instrument: Geotail CPI

Observatory: Geotail

Person: Prof. Louis A. Frank

Person: Dr. Kent L. Ackerson

Person: Jan Merka

Person: Dr. Robert E. McGuire

Person: UNKNOWN

Person: Guan Le

Person: Prof. Masaki Fujimoto

Repository: CDAWeb Data Repository FTP Interface

Repository: University of Iowa