A Review of the Space Environment Effects on Spacecraft in Different Orbits

Lu, Yaojuan; Shao, Qi; Yue, Honghao; Yang, Fei

doi:10.1109/access.2019.2927811

Cited by 98 publications

(57 citation statements)

References 105 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…[ 89,91 ] The sixth factor described by the NASA Marshall Space Flight Centre is the neutral atmosphere that influences the lifetime of spacecrafts components mainly because of the presence of atomic oxygen and high vacuum conditions. [ 92 ] While the former is responsible of several physical and chemical reactions like chemical bonds breaking, surface oxidation, and erosion of materials, [ 104 ] which can be mitigated through the use of anticorrosive materials and coatings; [ 105,106 ] vacuum induces several detrimental phenomena such as materials outgassing, adhesion and cold welding, materials evaporation, sublimation, and decomposition. [ 91,92 ] Hence, pressure control systems and sealing strategies are needed.…”

Section: Space Environment and Requirements For Space Solar Cellsmentioning

confidence: 99%

Solar Energy in Space Applications: Review and Technology Perspectives

Verduci

Romano

Brunetti

et al. 2022

Advanced Energy Materials

117

View full text Add to dashboard Cite

Solar cells (SCs) are the most ubiquitous and reliable energy generation systems for aerospace applications. Nowadays, III–V multijunction solar cells (MJSCs) represent the standard commercial technology for powering spacecraft, thanks to their high‐power conversion efficiency and certified reliability/stability while operating in orbit. Nevertheless, spacecraft companies are still using cheaper Si‐based SCs to amortize the launching costs of satellites. Moreover, in recent years, new SCs technologies based on Cu(In,Ga)Se2 (CIGS) and perovskite solar cells (PSCs) have emerged as promising candidates for aerospace power systems, because of their appealing properties such as lightweightness, flexibility, cost‐effective manufacturing, and exceptional radiation resistance. In this review the current advancements and future challenges of SCs for aerospace applications are critically discussed. In particular, for each type of SC, a description of the device's architecture, a summary of its performance, and a quantitative assessment of the radiation resistance are presented. Finally, considering the high potential that 2D‐materials (such as graphene, transition metal dichalcogenides, and transition metal carbides, nitrides, and carbonitrides) have in improving both performance and stability of SCs, a brief overview of some important results concerning the influence of radiation on both 2D materials‐based devices and monolayer of 2D materials is also included.

show abstract

Section: Space Environment and Requirements For Space Solar Cellsmentioning

confidence: 99%

Solar Energy in Space Applications: Review and Technology Perspectives

Verduci

Romano

Brunetti

et al. 2022

Advanced Energy Materials

117

View full text Add to dashboard Cite

show abstract

“…Heat sources are represented by the Sun, planets and other celestial bodies, which emit or reflect infrared radiation [13]; on the other hand, space can be represented as a black body acting as a heat sink with respect to the spacecraft. While in orbit around a planet or on its surface, as well as during interplanetary transfer, a space structure is typically subjected to external heat variations, which are often cyclic and typically lead to significant temperature changes and oscillations [14]. As a matter of fact, spacecraft surface temperatures can typically go from − 100 °C to 100 °C [7], or even fluctuate between − 120 °C and 120 °C.…”

Section: Space Environment Requirementsmentioning

confidence: 99%

Self-healing materials for space applications: overview of present development and major limitations

2021

View full text Add to dashboard Cite

In the last decade, self-healing materials have become extremely appealing for the field of space applications, due to their technological evolution and the consequent possibility of designing space systems and structures able to repair autonomously after damage arising from impacts with micrometeoroids and orbital debris, from accidental contact with sharp objects, from structural fatigue or simply due to material aging. The integration of these novel materials in the design of spacecraft structures would result in increased reliability and safety leading to longer operational life and missions. Such concepts will bring a decisive boost enabling new mission scenario for the establishment of new orbital stations, settlement on the Moon and human exploration of Mars.The proposed review aims at presenting the newest and most promising self-healing materials and associated technologies for space application, along with the issues related to their current technological limitations in combination with the effect of the space environment. An introductory part about the outlooks and challenges of space exploration and the self-healing concept is followed by a brief description of the space environment and its possible effects on the performance of materials. Self-healing materials are then analysed in detail, moving from the general intrinsic and extrinsic categories down to the specific mechanisms.

show abstract

“…Deep space exploration is mostly favored at Higher Earth Orbits (HEO), whereas LEO are particularly preferred for application service domains, terrain monitoring and climate change monitoring (Lu et al, 2019). A detailed list of the most prominent application uses and current research at LEO is presented in Table 2.…”

Section: Access Controlmentioning

confidence: 99%

Emerging IoT domains, current standings and open research challenges: a review

Ali

Ishak

Bhatti³

2021

PeerJ Computer Science

View full text Add to dashboard Cite

Over the last decade, the Internet of Things (IoT) domain has grown dramatically, from ultra-low-power hardware design to cloud-based solutions, and now, with the rise of 5G technology, a new horizon for edge computing on IoT devices will be introduced. A wide range of communication technologies has steadily evolved in recent years, representing a diverse range of domain areas and communication specifications. Because of the heterogeneity of technology and interconnectivity, the true realisation of the IoT ecosystem is currently hampered by multiple dynamic integration challenges. In this context, several emerging IoT domains necessitate a complete re-modeling, design, and standardisation from the ground up in order to achieve seamless IoT ecosystem integration. The Internet of Nano-Things (IoNT), Internet of Space-Things (IoST), Internet of Underwater-Things (IoUT) and Social Internet of Things (SIoT) are investigated in this paper with a broad future scope based on their integration and ability to source other IoT domains by highlighting their application domains, state-of-the-art research, and open challenges. To the best of our knowledge, there is little or no information on the current state of these ecosystems, which is the motivating factor behind this article. Finally, the paper summarises the integration of these ecosystems with current IoT domains and suggests future directions for overcoming the challenges.

show abstract

A Review of the Space Environment Effects on Spacecraft in Different Orbits

Cited by 98 publications

References 105 publications

Solar Energy in Space Applications: Review and Technology Perspectives

Solar Energy in Space Applications: Review and Technology Perspectives

Self-healing materials for space applications: overview of present development and major limitations

Emerging IoT domains, current standings and open research challenges: a review

Contact Info

Product

Resources

About