Thermal processing linked to Thermal processing, with source literature and related extracted records kept visible.
74%
Confidence
16
Literature sources
29
Linked simulants
224
Linked properties
Measurement type
Thermal processing
Application
Thermal processing
Primary source
Laser processing of lunar regolith simulants for beneficiation and metal extraction
Review state
needs review
atmosphere at a pressure of 1 bar in a 20 L vacuum chamber. Two types of experiments were conducted. First, preliminary experiments on the sintered simulants EAC-1A, JSC- 2A, and FJS-1 were conduct...
egree of roundness) over the sample temperature (compare with (d)). The characteristic temperatures are highlighted in the graphs: Start of sintering temperature (SST), deformation t
cused on the thermal properties, namely the specific heat capacity and the thermal conductivity. Several specimen of TUBS-M and TUBS-T were sintered at different temperatures with same holding time...
80 C lower than the highland samples, which required 1200 1215 C, excluding two samples that experienced minor oxidation. Variation in the sintering temperature was shown to be related to both comp...
chemical mechanical properties of phases occurred. Taguchi analysis implied that microstructural evolution is predominantly affected by the sintering temperature, whereas the other two factors (i.e...
es for the regolith simulants of type TUBS-M and TUBS-T, which are both comparable to the components LX- M100 and LX-T100. The investigated sintering temperature range was between 1100 C and 1500 C...
xial compression, and thermal property tests to evaluate the microstructural, mechanical, and thermal properties. The results show that the sintering temperature significantly affects both the micr...
. The morphology, chemical composition, structure, mechanical and thermal properties of the molten and SPSed samples were investigated. The sintering temperature signif- icantly influenced the micr...
P.-M. Kost, S. Linke, B. Gundlach, A. Lethuillier, J. Baasch, E. Stoll, J. Blum | 2021 | Acta Astronautica
DOI 10.1016/j.actaastro.2021.06.037B. A. Lomax, G. Charpentier, A. Nizet, A. Rützler, A. Kahan, F. McDonald, R. Lindner, J. D. Carpenter | 2025 | Materials Today Advances
DOI 10.1016/j.mtadv.2025.100620S. Gholami, X. Zhang, Y.-J. Kim, Y.-R. Kim, B. Cui, H.-S. Shin, J. Lee | 2022 | Materials & Design
DOI 10.1016/j.matdes.2022.110878J. Keuntje, T. Griemsmann, J. Patzwald, R. Staehr, P. Jaeschke, E. Stoll, S. Kaierle, L. Overmeyer | 2024 | Procedia CIRP
DOI 10.1016/j.procir.2024.08.131Y. Jiang, F. Li, S. Zhou, L. Liu | 2025 | Case Studies in Construction Materials
DOI 10.1016/j.cscm.2024.e04132Y. Liu, X. Zhang, X. Chen, C. Wang, Y. Yu, Y. Jia, W. Yao | 2024 | Crystals
DOI 10.3390/cryst14121022W. Han, L. Ding, L. Cai, J. Zhu, H. Luo, T. Tang | 2022 | Construction and Building Materials
DOI 10.1016/j.conbuildmat.2022.126655J.-C. Ginés-Palomares, M. Fateri, T. Schubert, L. D. P. d’Ambelle, S. Simon, G. J. G. Gluth, J. Günster, A. Zocca | 2023 | Scientific Reports
DOI 10.1038/s41598-023-50391-yX. Zhang, M. Khedmati, Y. Kim, H. Shin, J. Lee, Y. Kim, B. Cui | 2019 | Journal of the American Ceramic Society
DOI 10.1111/jace.16808P. Wang, F. Dang, Z. Wang, Y. Xia, Y. Zhou, C. Zhou | 2025 | Advances in Space Research
DOI 10.1016/j.asr.2025.08.013W. Han, Y. Zhou, F. Dang, C. Zhou, L. Ding | 2024 | Advances in Space Research
DOI 10.1016/j.asr.2023.11.027W. Han, Y. Zhou, L. Cai, C. Zhou, L. Ding | 2024 | International Journal of Mining Science and Technology
DOI 10.1016/j.ijmst.2024.06.004F. Dang, Y. Zhou, Z. Wang, Y. Li, P. Wang, C. Zhou | 2025 | Advances in Space Research
DOI 10.1016/j.asr.2024.09.030Y.-J. Kim, B. Ryu, H. Jin, J. Lee, H.-S. Shin | 2021 | Ceramics International
DOI 10.1016/j.ceramint.2021.06.09874%
16 sources