DYNAMO: A Mars upper atmosphere package for investigating solar wind interaction and escape processes, and mapping Martian fields

E. Chassefière; A. Nagy; M. Mandea; F. Primdahl; H. Rème; J. A. Sauvaud; R. Lin; S. Barabash; D. Mitchell; T. Zurbuchen; F. Leblanc; J. J. Berthelier; H. Waite; D. T. Young; J. Clarke; M. Parrot; J. G. Trotignon; J. L. Bertaux; E. Quèmerais; F. Barlier; K. Szegö; S. Szalä; S. Bougher; F. Forget; J. Lilensten; J. P. Barriot; G. Chanteur; J. Luhmann; G. Hulot; M. Purucker; D. Breuer; S. Smrekar; B. Jakosky; M. Menvielle; S. Sasaki; M. Acuna; G. Keating; P. Touboul; J. C. Gérard; P. Rochus; S. Orsini; G. Cerutti-Maori; J. Porteneuve; M. Meftah; Ch Malique

doi:10.1016/S0273-1177(03)00528-3

DYNAMO: A Mars upper atmosphere package for investigating solar wind interaction and escape processes, and mapping Martian fields

E. Chassefière
, A. Nagy
, M. Mandea
, F. Primdahl
, H. Rème
, J. A. Sauvaud
, R. Lin
, S. Barabash
, D. Mitchell
, T. Zurbuchen
, F. Leblanc
, J. J. Berthelier
, H. Waite
, D. T. Young
, J. Clarke
, M. Parrot
, J. G. Trotignon
, J. L. Bertaux
, E. Quèmerais
, F. Barlier

K. Szegö, S. Szalä, S. Bougher, F. Forget, J. Lilensten, J. P. Barriot, G. Chanteur, J. Luhmann, G. Hulot, M. Purucker, D. Breuer, S. Smrekar, B. Jakosky, M. Menvielle, S. Sasaki, M. Acuna, G. Keating, P. Touboul, J. C. Gérard, P. Rochus, S. Orsini, G. Cerutti-Maori, J. Porteneuve, M. Meftah, Ch Malique

Service d'Aéronomie
University of Michigan, Ann Arbor
Université Paris Diderot
Technical University of Denmark
IRAP/CNRS
University of California, Space Sciences Laboratory
Swedish Institute of Space Physics
Southwest Research Institute
Boston University
CNRS
Université Côte d’Azur
Wigner Research Centre for Physics
Université Grenoble Alpes
Observatoire Midi-Pyrénées
NASA Goddard Space Flight Center
University of Münster
Science Division
University of Colorado Boulder
University of Tokyo
George Washington University
ONERA Office National d'Etudes et Recherches Aerospatiales
University of Liège
INAF-IFSI

Research output: Contribution to journal › Article › peer-review

Abstract

DYNAMO is a small multi-instrument payload aimed at characterizing current atmospheric escape, which is still poorly constrained, and improving gravity and magnetic field representations, in order to better understand the magnetic, geologic and thermal history of Mars. The internal structure and evolution of Mars is thought to have influenced climate evolution. The collapse of the primitive magnetosphere early in Mars history could have enhanced atmospheric escape and favored transition to the present arid climate. These objectives are achieved by using a low periapsis orbit. DYNAMO has been proposed in response to the AO released in February 2002 for instruments to be flown as a complementary payload onboard the CNES Orbiter to Mars (MO-07), foreseen to be launched in 2007 in the framework of the French PREMIER Mars exploration program. MO-07 orbital phase 2b (with an elliptical orbit of periapsis 170 km), and in a lesser extent 2a, offers an unprecedented opportunity to investigate by in situ probing the chemical and dynamical properties of the deep ionosphere, thermosphere, and the interaction between the atmosphere and the solar wind, and therefore the present atmospheric escape rate. Ultraviolet remote sensing is an essential complement to characterize high, tenuous, layers of the atmosphere. One Martian year of operation, with about 5,000 low passes, should allow DYNAMO to map in great detail the residual magnetic field, together with the gravity field. Additional data on the internal structure will be obtained by mapping the electric conductivity, sinergistically with the NETLANDER magnetic data. Three options have been recommended by the International Science and Technical Review Board (ISTRB), who met on July 1st and 2nd, 2002. One of them is centered on DYNAMO. The final choice, which should be made before the end of 2002, will depend on available funding resources at CNES.

Original language	English
Pages (from-to)	2228-2235
Number of pages	8
Journal	Advances in Space Research
Volume	33
Issue number	12
DOIs	https://doi.org/10.1016/S0273-1177(03)00528-3
Publication status	Published - 1 Jan 2004
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 13 Climate Action

Keywords

Escape
Gravity field
Magnetic field
Mars
Upper atmosphere

Access to Document

10.1016/S0273-1177(03)00528-3

Cite this

Chassefière, E., Nagy, A., Mandea, M., Primdahl, F., Rème, H., Sauvaud, J. A., Lin, R., Barabash, S., Mitchell, D., Zurbuchen, T., Leblanc, F., Berthelier, J. J., Waite, H., Young, D. T., Clarke, J., Parrot, M., Trotignon, J. G., Bertaux, J. L., Quèmerais, E., ... Malique, C. (2004). DYNAMO: A Mars upper atmosphere package for investigating solar wind interaction and escape processes, and mapping Martian fields. Advances in Space Research, 33(12), 2228-2235. https://doi.org/10.1016/S0273-1177(03)00528-3

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title = "DYNAMO: A Mars upper atmosphere package for investigating solar wind interaction and escape processes, and mapping Martian fields",

abstract = "DYNAMO is a small multi-instrument payload aimed at characterizing current atmospheric escape, which is still poorly constrained, and improving gravity and magnetic field representations, in order to better understand the magnetic, geologic and thermal history of Mars. The internal structure and evolution of Mars is thought to have influenced climate evolution. The collapse of the primitive magnetosphere early in Mars history could have enhanced atmospheric escape and favored transition to the present arid climate. These objectives are achieved by using a low periapsis orbit. DYNAMO has been proposed in response to the AO released in February 2002 for instruments to be flown as a complementary payload onboard the CNES Orbiter to Mars (MO-07), foreseen to be launched in 2007 in the framework of the French PREMIER Mars exploration program. MO-07 orbital phase 2b (with an elliptical orbit of periapsis 170 km), and in a lesser extent 2a, offers an unprecedented opportunity to investigate by in situ probing the chemical and dynamical properties of the deep ionosphere, thermosphere, and the interaction between the atmosphere and the solar wind, and therefore the present atmospheric escape rate. Ultraviolet remote sensing is an essential complement to characterize high, tenuous, layers of the atmosphere. One Martian year of operation, with about 5,000 low passes, should allow DYNAMO to map in great detail the residual magnetic field, together with the gravity field. Additional data on the internal structure will be obtained by mapping the electric conductivity, sinergistically with the NETLANDER magnetic data. Three options have been recommended by the International Science and Technical Review Board (ISTRB), who met on July 1st and 2nd, 2002. One of them is centered on DYNAMO. The final choice, which should be made before the end of 2002, will depend on available funding resources at CNES.",

keywords = "Escape, Gravity field, Magnetic field, Mars, Upper atmosphere",

author = "E. Chassefi{\`e}re and A. Nagy and M. Mandea and F. Primdahl and H. R{\`e}me and Sauvaud, \{J. A.\} and R. Lin and S. Barabash and D. Mitchell and T. Zurbuchen and F. Leblanc and Berthelier, \{J. J.\} and H. Waite and Young, \{D. T.\} and J. Clarke and M. Parrot and Trotignon, \{J. G.\} and Bertaux, \{J. L.\} and E. Qu{\`e}merais and F. Barlier and K. Szeg{\"o} and S. Szal{\"a} and S. Bougher and F. Forget and J. Lilensten and Barriot, \{J. P.\} and G. Chanteur and J. Luhmann and G. Hulot and M. Purucker and D. Breuer and S. Smrekar and B. Jakosky and M. Menvielle and S. Sasaki and M. Acuna and G. Keating and P. Touboul and G{\'e}rard, \{J. C.\} and P. Rochus and S. Orsini and G. Cerutti-Maori and J. Porteneuve and M. Meftah and Ch Malique",

year = "2004",

month = jan,

day = "1",

doi = "10.1016/S0273-1177(03)00528-3",

language = "English",

volume = "33",

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journal = "Advances in Space Research",

issn = "0273-1177",

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Chassefière, E, Nagy, A, Mandea, M, Primdahl, F, Rème, H, Sauvaud, JA, Lin, R, Barabash, S, Mitchell, D, Zurbuchen, T, Leblanc, F, Berthelier, JJ, Waite, H, Young, DT, Clarke, J, Parrot, M, Trotignon, JG, Bertaux, JL, Quèmerais, E, Barlier, F, Szegö, K, Szalä, S, Bougher, S, Forget, F, Lilensten, J, Barriot, JP, Chanteur, G, Luhmann, J, Hulot, G, Purucker, M, Breuer, D, Smrekar, S, Jakosky, B, Menvielle, M, Sasaki, S, Acuna, M, Keating, G, Touboul, P, Gérard, JC, Rochus, P, Orsini, S, Cerutti-Maori, G, Porteneuve, J, Meftah, M & Malique, C 2004, 'DYNAMO: A Mars upper atmosphere package for investigating solar wind interaction and escape processes, and mapping Martian fields', Advances in Space Research, vol. 33, no. 12, pp. 2228-2235. https://doi.org/10.1016/S0273-1177(03)00528-3

TY - JOUR

T1 - DYNAMO

T2 - A Mars upper atmosphere package for investigating solar wind interaction and escape processes, and mapping Martian fields

AU - Chassefière, E.

AU - Nagy, A.

AU - Mandea, M.

AU - Primdahl, F.

AU - Rème, H.

AU - Sauvaud, J. A.

AU - Lin, R.

AU - Barabash, S.

AU - Mitchell, D.

AU - Zurbuchen, T.

AU - Leblanc, F.

AU - Berthelier, J. J.

AU - Waite, H.

AU - Young, D. T.

AU - Clarke, J.

AU - Parrot, M.

AU - Trotignon, J. G.

AU - Bertaux, J. L.

AU - Quèmerais, E.

AU - Barlier, F.

AU - Szegö, K.

AU - Szalä, S.

AU - Bougher, S.

AU - Forget, F.

AU - Lilensten, J.

AU - Barriot, J. P.

AU - Chanteur, G.

AU - Luhmann, J.

AU - Hulot, G.

AU - Purucker, M.

AU - Breuer, D.

AU - Smrekar, S.

AU - Jakosky, B.

AU - Menvielle, M.

AU - Sasaki, S.

AU - Acuna, M.

AU - Keating, G.

AU - Touboul, P.

AU - Gérard, J. C.

AU - Rochus, P.

AU - Orsini, S.

AU - Cerutti-Maori, G.

AU - Porteneuve, J.

AU - Meftah, M.

AU - Malique, Ch

PY - 2004/1/1

Y1 - 2004/1/1

N2 - DYNAMO is a small multi-instrument payload aimed at characterizing current atmospheric escape, which is still poorly constrained, and improving gravity and magnetic field representations, in order to better understand the magnetic, geologic and thermal history of Mars. The internal structure and evolution of Mars is thought to have influenced climate evolution. The collapse of the primitive magnetosphere early in Mars history could have enhanced atmospheric escape and favored transition to the present arid climate. These objectives are achieved by using a low periapsis orbit. DYNAMO has been proposed in response to the AO released in February 2002 for instruments to be flown as a complementary payload onboard the CNES Orbiter to Mars (MO-07), foreseen to be launched in 2007 in the framework of the French PREMIER Mars exploration program. MO-07 orbital phase 2b (with an elliptical orbit of periapsis 170 km), and in a lesser extent 2a, offers an unprecedented opportunity to investigate by in situ probing the chemical and dynamical properties of the deep ionosphere, thermosphere, and the interaction between the atmosphere and the solar wind, and therefore the present atmospheric escape rate. Ultraviolet remote sensing is an essential complement to characterize high, tenuous, layers of the atmosphere. One Martian year of operation, with about 5,000 low passes, should allow DYNAMO to map in great detail the residual magnetic field, together with the gravity field. Additional data on the internal structure will be obtained by mapping the electric conductivity, sinergistically with the NETLANDER magnetic data. Three options have been recommended by the International Science and Technical Review Board (ISTRB), who met on July 1st and 2nd, 2002. One of them is centered on DYNAMO. The final choice, which should be made before the end of 2002, will depend on available funding resources at CNES.

AB - DYNAMO is a small multi-instrument payload aimed at characterizing current atmospheric escape, which is still poorly constrained, and improving gravity and magnetic field representations, in order to better understand the magnetic, geologic and thermal history of Mars. The internal structure and evolution of Mars is thought to have influenced climate evolution. The collapse of the primitive magnetosphere early in Mars history could have enhanced atmospheric escape and favored transition to the present arid climate. These objectives are achieved by using a low periapsis orbit. DYNAMO has been proposed in response to the AO released in February 2002 for instruments to be flown as a complementary payload onboard the CNES Orbiter to Mars (MO-07), foreseen to be launched in 2007 in the framework of the French PREMIER Mars exploration program. MO-07 orbital phase 2b (with an elliptical orbit of periapsis 170 km), and in a lesser extent 2a, offers an unprecedented opportunity to investigate by in situ probing the chemical and dynamical properties of the deep ionosphere, thermosphere, and the interaction between the atmosphere and the solar wind, and therefore the present atmospheric escape rate. Ultraviolet remote sensing is an essential complement to characterize high, tenuous, layers of the atmosphere. One Martian year of operation, with about 5,000 low passes, should allow DYNAMO to map in great detail the residual magnetic field, together with the gravity field. Additional data on the internal structure will be obtained by mapping the electric conductivity, sinergistically with the NETLANDER magnetic data. Three options have been recommended by the International Science and Technical Review Board (ISTRB), who met on July 1st and 2nd, 2002. One of them is centered on DYNAMO. The final choice, which should be made before the end of 2002, will depend on available funding resources at CNES.

KW - Escape

KW - Gravity field

KW - Magnetic field

KW - Mars

KW - Upper atmosphere

UR - https://www.scopus.com/pages/publications/2442691793

U2 - 10.1016/S0273-1177(03)00528-3

DO - 10.1016/S0273-1177(03)00528-3

M3 - Article

AN - SCOPUS:2442691793

SN - 0273-1177

VL - 33

SP - 2228

EP - 2235

JO - Advances in Space Research

JF - Advances in Space Research

IS - 12

ER -

DYNAMO: A Mars upper atmosphere package for investigating solar wind interaction and escape processes, and mapping Martian fields

Abstract

UN SDGs

Keywords

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