Experimental results from the ST7 mission on LISA Pathfinder

Anderson, G. M.; Anderson, J. B.; Anderson, Maxwell G.; Aveni, G.; Bame, David; Barela, Phillip; Blackman, Kathie; Carmain, A.; Chen, L.; Cherng, Michael; Clark, Stephanie Joy; Connally, M.; Connolly, William; Conroy, David G.; Cooper, Mark Ian; Cutler, Curt; D'Agostino, Jeff; Demmons, Nathaniel; Dorantes, E.; Dunn, Charles; Duran, Muhammet Emin; Ehrbar, Eric; Evans, John E.; Fernández, Juan M.; Franklin, G.; Girard, M. A.; Gorelik, Jacob; Hruby, Vlad; Hsu, Oscar; Jackson, Daniel; Javidnia, Shahram; Kern, Dennis L.; Knopp, Mike; Kolasinski, Robert; Kuo, Cheng-Ling; Le, Thanh; Li, I.; Liepack, Otfrid G.; Littlefield, Alan C.; Maghami, Peiman G.; Malik, S.L.; Markley, L.; Martin, Roy; Marrese-Reading, Colleen; Mehta, Jitendra; Mennela, J.; Miller, Darcy; Nguyen, D.; O’Donnell, Jim; Parikh, R.; Plett, G. A.; Ramsey, Thomas; Randolph, Thomas; Rhodes, Steven C.; Romero-Wolf, A.; Roy, Tom; Ruiz, Alyssa; Shaw, Harry; Slutsky, J.; Spence, Douglas; Stocky, J. F.; Tallon, J.; Thorpe, Ira; Tolman, W.; Umfress, H.; Valencia, Renato; Cozzani, Valerio; Warner, William S.; Wellman, John B.; Willis, Peter; Ziemer, John; Zwahlen, Jurg; Armano, M.; Audley, H.; Baird, J.; Binétruy, P.; Born, M.; Bortoluzzi, D.; Castelli, E.; Cavalleri, A.; Cesarini, A.; Cruise, A. M.; Danzmann, K.; Silva, M. de Deus; Diepholz, I.; Dixon, G. J.; Dolesi, R.; Ferraioli, L.; Ferroni, V.; Fitzsimons, E.; Freschi, M.; Gesa, L.; Gibert, F.; Giardini, Domenico; Giusteri, R.; Grimani, C.; Grzymisch, J.; Harrison, I.; Heinzel, Gerhard; Hewitson, M.; Hollington, D.; Hoyland, D.; Hueller, M.; Inchauspé, H.; Jennrich, O.; Jetzer, Philippe; Karnesis, Nikolaos; Kaune, B.; Korsakova, Natalia; Killow, C. J.; Lobo, J. A.; Lloro, I.; Liu, L.; López-Zaragoza, J. P.; Maarschalkerweerd, R.; Mance, D.; Meshksar, N.; Martín, Vicente; Martin-Polo, L.; Martino, J.; Martín-Porqueras, F.; Mateos, I.; McNamara, P. W.; Mendes, José F. G.; Mendes, L.; Nofrarias, M.; Paczkowski, S.; Perreur-Lloyd, M.; Petiteau, Antoine; Pivato, P.; Plagnol, E.; Ramos‐Castro, J.; Reiche, J.; Robertson, D. I.; Rivas, F.; Russano, G.; Sopuerta, Carlos F.; Sumner, T. J.; Texier, D.; Vetrugno, D.; Vitale, S.; Wanner, Gudrun; Ward, H.; Wass, Peter; Weber, William J.; Wissel, L.; Wittchen, A.; Zweifel, Peter

doi:10.1103/physrevd.98.102005

Cited by 64 publications

(34 citation statements)

References 3 publications

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“…In table II, comparison between April 2016 and January 2017 data sets allows to appreciate the consistency between the "noise runs" and the time-invariance of the sensor and actuator performances. It is worth mentioning that independent studies by [18] also show consistent results and similar performances for the cold-gas thrusters at different times of the mission (September 2016 and April 2017).…”

Section: The Drag-free and Attitude Control System (Dfacs) -supporting

confidence: 63%

“…The S/C force noise curve (turquoise) is due to the micro-thruster noise, for movements along X and rotation around Y. This has been demonstrated by comparing the colloidal and cold gas micronewton thruster systems independently and jointly [18]. Note that the presence of a strong GRS sensing noise component, around 0.1Hz, is due to the control strategy.…”

Section: The Drag-free and Attitude Control System (Dfacs) -mentioning

confidence: 87%

“…to a Galilean frame and the micro-propulsion system, a set of six cold gas thrusters (a technology already flown in space with ESA's Gaia mission [5] and CNES 's MICROSCOPE mission [4]), allows S/C displacement and attitude control along its six degrees of freedom. Note that LPF also has a NASA participation, the Space Technology 7 (ST7 ) mission, contributing a set of eight colloidal thrusters and the electronics/computer that control them [18].…”

mentioning

confidence: 99%

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LISA Pathfinder platform stability and drag-free performance

Armano¹,

Audley²,

Baird³

et al. 2019

Phys. Rev. D

Self Cite

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Section: The Drag-free and Attitude Control System (Dfacs) -supporting

confidence: 63%

Section: The Drag-free and Attitude Control System (Dfacs) -mentioning

confidence: 87%

mentioning

confidence: 99%

See 1 more Smart Citation

LISA Pathfinder platform stability and drag-free performance

Armano¹,

Audley²,

Baird³

et al. 2019

Phys. Rev. D

Self Cite

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“…Figure 2 shows an optomechanical and cryomagnetic seismometer concept for LGWA, together with the noise performance of the Mars Insight Very Broadband (VBB) sensors and of the LISA Pathfinder (LPF) mission (Armano et al 2016;Anderson et al 2018), which is the best acceleration sensitivity ever achieved at mHz frequencies. The Mars Insight model combines the position and velocity readouts of the suspended masses.…”

Section: Detector Conceptmentioning

confidence: 99%

Lunar Gravitational-wave Antenna

Harms

Ambrosino

Angelini

et al. 2021

ApJ

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“…While this mission is testing a combustion‐based thruster, ionic liquids have also been used for electrospray thruster missions. For instance, ESA's LISA‐Pathfinder mission tested an electrospray system, using an ionic liquid propellant (1‐ethyl‐3‐methylimidazolium bis(trifluoromethylsulfonyl)imide), which performed very successfully …”

Section: Green Il‐based Propellantsmentioning

confidence: 99%

Electrospray ionization enters the final frontier: Mass spectrometry's role in understanding electrospray thrusters and their plumes

Patrick

2020

Rapid Comm Mass Spectrometry

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Electrospray thrusters using ionic liquid (IL)-based propellants are quickly gaining popularity in spacecraft design. Mass spectrometry is especially well-suited to provide important knowledge on the fundamentals of how these systems work and on evaluating their efficiencies and impacts, given that the operating principles of electrospray thrusters closely mimics the mass spectrometry experimentin both ions are generated by electrospray and then enter a vacuum. Here, electrospray thruster technology and IL-based propellants are briefly introduced. This introduction is then followed by a discussion of mass spectrometry's current contribution to the study of IL-based electrospray thrusters with a focus on electrospray, dissociation, and spectroscopy studiesand a brief discussion of areas ripe for immediate contributions from the mass spectrometry community.

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Experimental results from the ST7 mission on LISA Pathfinder

Cited by 64 publications

References 3 publications

LISA Pathfinder platform stability and drag-free performance

LISA Pathfinder platform stability and drag-free performance

Lunar Gravitational-wave Antenna

Electrospray ionization enters the final frontier: Mass spectrometry's role in understanding electrospray thrusters and their plumes

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