Commit da96090adfb940a86a7dcbce4e7d33b526804e07

Authored by Benjamin Renard
1 parent 9c1110d6

Solar Orbiter MAG & RPW descriptions

Instrument/CDPP-AMDA/Solar_Orbiter/MAG.xml
... ... @@ -7,8 +7,39 @@
7 7 <ResourceName>MAG</ResourceName>
8 8 <AlternateName>Magnetometer</AlternateName>
9 9 <ReleaseDate>2018-10-27T18:45:12Z</ReleaseDate>
10   - <Description>
11   - </Description>
  10 + <Description>The magnetometer is a unique instrument on Solar Orbiter in that it provides essential
  11 +information about both the largest scale structures in space around the Sun, as well as the
  12 +smallest scale kinetic processes in the plasma. Indeed, the magnetic field plays a central role in
  13 +plasma dynamics since charged particles generally travel along the magnetic field, making it
  14 +the route from the Sun into space. The accurate measurement of the local magnetic field is
  15 +therefore central to the scientific success of Solar Orbiter. Magnetometer data are expected to
  16 +lead to significant advances in our understanding of how the Sun’s magnetic field links into
  17 +space and evolves over the solar cycle; how particles are accelerated and propagate around the
  18 +solar system, including to the Earth; and how the corona and solar wind are heated and
  19 +accelerated, among many others.
  20 +
  21 +The MAG team science objectives include:
  22 +* How does the Sun’s magnetic field link into space?
  23 +* How does the heliospheric magnetic field disconnect from the Sun?
  24 +* How does the Sun’s magnetic field change over time?
  25 +* How is the heliospheric current sheet related to coronal structure?
  26 +* What is the role of ICMEs in the Sun’s magnetic cycle?
  27 +* What is the origin of the slow speed solar wind?
  28 +* What drives the evolution of the solar wind distribution?
  29 +* What are the origins of waves, turbulence and small scale structures?
  30 +* How is turbulent energy dissipated?
  31 +* What are the properties of near-Sun shocks and the fluctuations around them?
  32 +* What is the structure of plasma turbulence and how does it evolve?
  33 +* How do large and small scale structures modulate particle fluxes?
  34 +
  35 +In order to achieve these objectives, the magnetometer will measure the magnetic field
  36 +continuously with sufficient cadence and precision to quantify fluid-scale phenomena
  37 +throughout the mission and, in burst mode, with sufficient cadence and precision to study ion
  38 +kinetic phenomena.
  39 +
  40 +Low latency data are generated at a very low cadence compared to normal magnetometer data
  41 +and are intended for rapid, broad characterisation of solar wind conditions at the spacecraft
  42 +location.</Description>
12 43 <Acknowledgement></Acknowledgement>
13 44 <Contact>
14 45 <PersonID>spase://SMWG/Person/Tim.Horbury</PersonID>
... ...
Instrument/CDPP-AMDA/Solar_Orbiter/RPW.xml
... ... @@ -7,7 +7,63 @@
7 7 <ResourceName>RPW</ResourceName>
8 8 <AlternateName>Plasma Wave Investigation</AlternateName>
9 9 <ReleaseDate>2017-11-27T21:10:13Z</ReleaseDate>
10   - <Description/>
  10 + <Description>RPW will make key measurements in support of the first three, out of four top-level scientific questions,
  11 +which drive Solar Orbiter overall science objectives:
  12 +* How and where do the solar wind plasma and magnetic field originate in the corona?
  13 +* How do solar transients drive heliospheric variability?
  14 +* How do solar eruptions produce energetic particle radiation that fills the heliosphere?
  15 +* How does the solar dynamo work and drive connections between the Sun and the heliosphere?
  16 +
  17 +Here is the summary of the specific RPW Science Objectives.
  18 +* Solar and Interplanetary Radio Burst:
  19 + - What is the role of shocks and flares in accelerating particles near the Sun?
  20 + - How is the Sun connected magnetically to the interplanetary medium?
  21 + - What are the sources and the global dynamics of eruptive events?
  22 + - What is the role of ambient medium conditions on particle acceleration and propagation?
  23 + - How do variations and structure in the solar wind affect low frequency radio wave propagation?
  24 +* Electron density and temperature measurements with the Quasi-Thermal Noise spectroscopy:
  25 + - Precise measurement of both the electron density and temperature, with accuracies respectively of
  26 + a few % and around 10 %, at perihelion.
  27 + - Study the non-thermal character of the electron distributions at perihelion.
  28 +* Radio emission processes from electron beams: Langmuir waves and electromagnetic mode conversion:
  29 + - Measurements for the first time in the Solar Wind of both the electric and magnetic field waveforms
  30 + at high time resolution (up to 500 kSs).
  31 + - Study of the mode conversion from Langmuir to electromagnetic waves.
  32 + - Study of the energy balance between electron beams, Langmuir waves and e.m. radio waves at
  33 + several radial distances
  34 +* Solar wind microphysics and turbulence:
  35 + - Measure of the waves associated with the plasma instabilities that are generated by temperature
  36 + anisotropies in the solar wind.
  37 + - First DC/LF electric field measurements in the inner heliosphere and over a large radial distance
  38 + in the solar.
  39 +* Shocks, Reconnection, Current Sheets, and Magnetic Holes:
  40 + - Identification and study of the reconnection process in current sheets with thickness down to the ion
  41 + scales and smaller.
  42 + - Determination of the interplanetary shock structure down to the spatial and temporal scales comparable
  43 + and smaller than the typical ion scales.
  44 + - Determination of different particle energisation mechanisms within shocks and reconnection regions.
  45 + - Distinguish different radio burst generation mechanisms. Interplanetary Dust
  46 + - Determination, in combination with the EPD instrument, the spatial distribution, mass and dynamics
  47 + of dust particles in the near-Sun heliosphere, in and out of the ecliptic.
  48 +
  49 +To cover its specific Science Objectives, RPW will measure magnetic and electric fields at high time
  50 +resolution using a number of sensors, to determine the characteristics of electromagnetic and electrostatic
  51 +waves in the solar wind. More precisely, RPW will:
  52 +* Make the first-ever high accuracy, high-sensitivity and low noise measurements of electric fields
  53 + at low frequencies (below ~1 kHz) in the inner Heliosphere.
  54 +* Measure the magnetic and electric fields of the solar wind turbulence with high sensitivity and
  55 + dynamic range along the spacecraft trajectory.
  56 +* Store high-resolution data from scientifically interesting regions such as in-situ shock crossings,
  57 + in-situ Type III events and others.
  58 +* Measure the satellite potential with high temporal resolution permitting to estimate the density
  59 + fluctuations in the solar wind and allowing higher accuracy particle instrument measurements.
  60 +* Measure the quasi thermal noise and Langmuir waves around the local plasma frequency
  61 +* Measure for the first type the high frequency magnetic counterpart of Langmuir waves associated
  62 + with in-situ Type III bursts
  63 +* Observe the solar and interplanetary radio burst
  64 +* Observe the radio counterpart of dust particle impacts
  65 +* Detect on-board in-situ shock crossings and store the corresponding data
  66 +* Detect on-board in-situ Type III events and store the corresponding data</Description>
11 67 <Acknowledgement/>
12 68 <Contact>
13 69 <PersonID>spase://SMWG/Person/Milan.Maksimovic</PersonID>
... ...