FORESAIL‐1 CubeSat Mission to Measure Radiation Belt Losses and Demonstrate Deorbiting

Palmroth, Minna; Praks, Jaan; Vainio, R.; Janhunen, P.; Kilpua, Emilia; Afanasiev, Alexandr; Ala‐Lahti, Matti; Alho, A.; Asikainen, Timo; Asvestari, Eleanna; Battarbee, Markus; Binios, Alexandros; Bosser, Alexandre Louis; Brito, Thiago; Dubart, Maxime; Envall, Jouni; Ganse, Urs; Ganushkina, N. Y.; George, Harriet; Gieseler, J.; Good, Simon; Grandin, Maxime; Haslam, Sean; Hedman, Hannu‐Pekka; Hietala, Heli; Jovanovic, Nemanja; Kakakhel, Syed Rameez Ullah; Kalliokoski, Milla; Kettunen, V. V.; Koskela, T.; Lumme, E.; Meskanen, Matias; Morosan, Diana; Mughal, M. Rizwan; Niemelä, Petri; Nyman, Samuli; Oleynik, P.; Osmane, Adnane; Palmerio, Erika; Peltonen, J.; Pfau‐Kempf, Yann; Plosila, Juha; Polkko, J.; Poluianov, Stepan; Pomoell, Jens; Price, Daniel J.; Punkkinen, Arttu; Punkkinen, Risto; Riwanto, Bagus; Salomaa, Lassi; Slavinskis, Andris; Säntti, Tero; Tammi, Jani; Tenhunen, Hannu; Toivanen, Petri; Tuominen, Johanna; Turc, Lucile; Валтонен, Э.; Virtanen, Pasi; Westerlund, Tomi

doi:10.1029/2018ja026354

Cited by 27 publications

(17 citation statements)

References 72 publications

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“…It is evident from the executive summary of ISS, which encapsulates the achievements of innovative research on the orbiting laboratory that had created a positive impact on the quality of life on Earth and the future scope of the interdisciplinary researches globally for creating an impact on scientific advancement. [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16] Herein we conduct theoretical studies for providing the proof of the concept of space debris recycling and energy conversion system in a microgravity environment with an intention to carry out real-time experiments in the space platform through the multinational collaboration with wide scope and benefits to humanity. The emerging application of outer space for the progression of the standard of living and quest for wisdom has led to the growth of space debris or space junk in orbits where the large number of satellites is operational.…”

Section: Introductionmentioning

confidence: 99%

“…Various reports and industrial engineering data on the usefulness of the prevailing debris extenuation methods are inadequate for a realistic conclusion. [4][5][6][7][8][9][10][11][12][13][14][15][16] The present trend of global space activities indicates that in the ensuing decades' huge volumes of space debris will be in orbit and there is a need to update the debris alleviation normal exercises to stimulate competent and active practices to better abate the risks from space debris for the benign maneuvers of future space missions. [4][5][6][7]14 The fact is that even if all the upcoming space launches are called off, the space debris that already exists will be tendering threats for numerous decades to come before all of them re-enter the earth and burn off.…”

Section: Introductionmentioning

confidence: 99%

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Theoretical studies on space debris recycling and energy conversion system in the International Space Station

Mariappan

Kumar

Weddell

et al. 2020

Engineering Reports

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The space debris management and alleviation in the microgravity environment is a dynamic research theme of contemporary interest. Herein, we provide a theoretical proof of the concept of a lucrative energy conversion system that is capable of changing the space debris into useful powders in the International Space Station (ISS) for various bids. A specially designed broom is adapted to collect the space debris of various sizes. An optical sorting method is proposed for the debris segregation in the ISS by creating an artificial gravitational field.It could be done by using the frame-dragging effect or gravitomagnetism. An induction furnace is facilitated for converting the segregated metal-scrap into liquid metal. A fuel-cell aided water atomization method is proposed for transforming the liquid debris into metal powder. The high-energetic metal powders obtained from the space debris could be employed for producing propellants for useful aerospace applications, and the silicon powder obtained could be used for making soil for fostering the pharmaceutical-flora in the space lab in the future aiming for the scarce-drug discoveries for high-endurance health care management. The proposed energy conversion system is a possible alternative for the space debris extenuation and its real applications in orbiting laboratories through the international collaboration for the benefits to humanity.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Theoretical studies on space debris recycling and energy conversion system in the International Space Station

Mariappan

Kumar

Weddell

et al. 2020

Engineering Reports

View full text Add to dashboard Cite

show abstract

“…Literature review reveals that through fundamental research and development a few products and services derived from space station activities are entering the souk and furthering healthy and peaceful life on Earth [1], which is motivating us to propose more challenging research in ISS. It is evident from the executive summary of ISS, which encapsulates the achievements of innovative research on the orbiting laboratory that had created a positive impact on the quality of life on Earth and the future scope of the interdisciplinary researches globally for creating an impact on scientific advancement [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16]. Herein we conduct theoretical studies for providing the proof of the concept of space debris recycling and energy conversion system in a microgravity environment with an intention to carry out real-time experiments in the space platform through the multi-national collaboration with wide scope and benefits to humanity.…”

Section: Introductionmentioning

confidence: 99%

“…The growing utilization of outer space for the advancement of the standard of living and hunt for wisdom has led to the accretion of space debris or space junk in high-density satellites orbits. Various reports and industrial engineering data on the usefulness of the prevailing debris extenuation methods are inadequate for a realistic conclusion [4][5][6][7][8][9][10][11][12][13][14][15][16]. J.-C. Liou et al [4][5][6][7][8] reported that as the space debris volume remains to rise over time due to the global space activities in recent years, there is a need to update the debris alleviation normal exercises to stimulate competent and active practices to better abate the risks from space debris for the benign manoeuvres of future space missions.…”

Section: Introductionmentioning

confidence: 99%

Theoretical studies on space debris recycling and energy conversion system in International space station

Mariappan¹,

Weddell

et al. 2020

Preprint

View full text Add to dashboard Cite

The space debris management and alleviation in the microgravity environment is a dynamic research theme of contemporary interest. Herein, we provide a theoretical proof of the concept of a lucrative energy conversion system that is capable for changing the space debris into useful powders in the international space station (ISS) for various bids. A specially designed broom is adapted to collect the space debris of various sizes. An optical sorting method is proposed for the debris segregation in the ISS by creating an artificial gravitational field using frame-dragging or gravitomagnetism. An induction furnace is facilitated for converting the segregated metal-scrap into liquid metal. A fuel-cell aided water atomization method is proposed for transforming the liquid debris into metal powder. The high-energetic metal powders obtained from the space debris could be employed for producing propellants for useful aerospace applications, and the silicon powder obtained could be used for making soil for fostering the pharmaceutical-flora in the space lab in the future aiming for the scarce-drug discoveries for high-endurance health care management. The proposed energy conversion system is a possible alternative for the space debris extenuation, and its real applications in orbiting laboratories through the international collaboration for the benefits to humanity.

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“…Vlasiator (http://www.physics.helsinki. fi/vlasiator/) is distributed under the GPL-2 open source license (Palmroth et al, 2019). To learn more, see von Alfthan et al (2020).…”

mentioning

confidence: 99%

Comparative Analysis of the Vlasiator Simulations and MMS Observations of Multiple X‐Line Reconnection and Flux Transfer Events

et al. 2020

Self Cite

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The Vlasiator hybrid‐Vlasov code was developed to investigate global magnetospheric dynamics at ion‐kinetic scales. Here we focus on the role of magnetic reconnection in the formation and evolution of magnetic islands at the low‐latitude magnetopause, under southward interplanetary magnetic field conditions. The simulation results indicate that (1) the magnetic reconnection ion kinetics, including the Earthward pointing Larmor electric field on the magnetospheric side of an X‐point and anisotropic ion distributions, are well‐captured by Vlasiator, thus enabling the study of reconnection‐driven magnetic island evolution processes, (2) magnetic islands evolve due to continuous reconnection at adjacent X‐points, “coalescence” which refers to the merging of neighboring islands to create a larger island, “erosion” during which an island loses magnetic flux due to reconnection, and “division” which involves the splitting of an island into smaller islands, and (3) continuous reconnection at adjacent X‐points is the dominant source of magnetic flux and plasma to the outer layers of magnetic islands resulting in cross‐sectional growth rates up to + 0.3 RE2/min. The simulation results are compared to the Magnetospheric Multiscale (MMS) measurements of a chain of ion‐scale flux transfer events (FTEs) sandwiched between two dominant X‐lines. The MMS measurements similarly reveal (1) anisotropic ion populations and (2) normalized reconnection rate ~0.18, in agreement with theory and the Vlasiator predictions. Based on the simulation results and the MMS measurements, it is estimated that the observed ion‐scale FTEs may grow Earth‐sized within ~10 min, which is comparable to the average transport time for FTEs formed in the subsolar region to the high‐latitude magnetopause. Future simulations shall revisit reconnection‐driven island evolution processes with improved spatial resolutions.

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FORESAIL‐1 CubeSat Mission to Measure Radiation Belt Losses and Demonstrate Deorbiting

Cited by 27 publications

References 72 publications

Theoretical studies on space debris recycling and energy conversion system in the International Space Station

Theoretical studies on space debris recycling and energy conversion system in the International Space Station

Theoretical studies on space debris recycling and energy conversion system in International space station

Comparative Analysis of the Vlasiator Simulations and MMS Observations of Multiple X‐Line Reconnection and Flux Transfer Events

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