Effects of thermal factors on the microstructure and properties of electromagnetic induction-sintered HUST-1 simulated lunar soil

P. Wang, F. Dang, Z. Wang, Y. Xia, Y. Zhou, C. Zhou | 2025 | Advances in Space Research

DOI 10.1016/j.asr.2025.08.013

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Summary

10.1016/j.asr.2025.08.013 Effects of thermal factors on the microstructure and properties of electromagnetic induction-sintered HUST-1 simulated lunar soil Advances in Space Research Journal fla 02731177 76 9 5504 5517 5504-5517 9 2025-11-01 1 November 2025 2025 COSPAR. Published by Elsevier B.V. All rights are reserved, including those for text and data mining, AI training, and similar technologies. COSPAR. Published by Elsevier B.V. All rights are reserved, including those for text and data mining, AI training, and similar technologies. Wang, Penglin Dang, Fen Wang, Zekai Xia, Yifeng Zhou, Yan Zhou, Cheng In-situ lunar regolith formation is a crucial approach for establishing a long-term lunar base. Electromagnetic induction sintering has been applied for the first time to fabricate dense components for lunar architecture. This study explored the adaptation range of induction sintering The paper investigates the effects of thermal factors on the microstructure and properties of sintered samples made from HUST-1 simulated lunar soil. The study includes characterization of the material, sintering processes, and tests for mechanical and thermal physical properties. The results highl

Connected extracted records

These are the records this paper contributes to the simulant, returned sample, method, and property browsers.

Used simulants

HUST-1

simulated lunar soil

Needs review

100% confidencepage 11

KLS-1

reference

Needs review

50% confidencepage 25

JSC-1A

characterized

Needs review

100% confidencepage 27

Returned samples

No returned samples extracted yet.

Experiments and measurements

Induction sintering

Sintering process

Needs review

Specimen preparation procedure, Induction sintering95% confidencepage 3

Porosity and density test

Physical property testing

Needs review

Porosity and density test of sintered samples95% confidencepage 3

Compressive strength and strain testing

Mechanical property testing

Needs review

Compressive strength and strain testing95% confidencepage 4

Hardness tests

Mechanical property testing

Needs review

Hardness tests95% confidencepage 4

Thermal physical properties test

Thermal property testing

Needs review

Thermal physical properties test of sintered samples95% confidencepage 4

Analysis of the influence of thermal factors

Thermal effect analysis

Needs review

Analysis of the influence of thermal factors on sintered samples95% confidencepage 4

Data Analysis

Quantitative

Needs review

Statistical analysis, Data visualization70% confidencepage 8

Model Simulation

Computational

Needs review

Simulation, Modeling65% confidencepage 8

Measured properties

Porosity

Measured

Needs review

Physical95% confidencepage 3

Density

Measured

Needs review

Physical95% confidencepage 3

Compressive strength

Measured

Needs review

Mechanical95% confidencepage 4

Hardness

Measured

Needs review

Mechanical95% confidencepage 4

Thermal physical properties

Measured

Needs review

Thermal95% confidencepage 4

Microstructure

Analyzed

Needs review

Structural95% confidencepage 3

Phase composition

Analyzed

Needs review

Structural95% confidencepage 3

Thermal effects

Analyzed

Needs review

Thermal95% confidencepage 4

Methods and applications

Methods

sinteringcompression testingInduction sinteringPorosity and density testCompressive strength and strain testingHardness testsThermal physical properties testAnalysis of the influence of thermal factorsData AnalysisModel SimulationSupplementary InformationDocument AnalysisSintering at different temperatures, dwell times, and electric current frequencyMechanical testing (compressive strength, strain, hardness)Thermal testing (expansion, conductivity, heat capacity, diffusion)XRD analysis of crystalline structureEDS analysis of chemical compositionNanoindentation for microscale hardness and elastic modulusMIP analysis for pore size distributionTaguchi method for experimental optimizationelectromagnetic induction sinteringTaguchi analysiscompressive strength testingthermal properties testingmicrostructure analysisXRFlaser diffractionSEM-EDSDSCTGelectromagnetic inductionTaguchi methodologynanoindentationthermal diffusivity measurementcompressive strength measurementVickers hardness measurementX-ray diffraction (XRD)Scanning Electron Microscopy (SEM)density measurementthermal factorscurrent frequencydwell timesintering temperaturespecimen MS8-T3D2F1Taguchi L9 orthogonal arrayAutomatic Envelope Density AnalyzerEDSXRD analysisstress strain curveVickers hardness testsnanoindentation testsCTE testslaser thermal conductivity analyzerforce displacement curvesthermal cyclingMinilab softwareS/N ratio calculationmin max normalizationthermal conductivity measurementspecific heat capacity measurementcoefficient of thermal expansion measurementcoefficient of thermal diffusion measurementspark plasma sinteringthermal shock resistancesintering parametersmicrostructure characteristicsmechanical propertiesdensificationmicrostructural evolutionmechanical characteristicsMicrowave sinteringHigh-frequency induction heated press sinteringVariable speed induction sinteringHigh-frequency induction heatingInduction heating sinteringElectrophoretic depositionExtrusion-3D-printing sinteringTaguchi Design of ExperimentSintering temperature effectsPhase transformation

Applications

Thermal processingConstruction and infrastructureIn-situ resource utilization (ISRU)Lunar base constructionSpace exploration materialsThermal property analysis of lunar simulantsAcademic ResearchData ScienceEngineeringScientific CommunicationLunar soil simulation for space explorationMaterial science research for advanced ceramics and compositesThermal and mechanical property analysis for aerospace applicationsOptimization of sintering processes for industrial manufacturingStructural and chemical analysis of materials for material characterizationlunar architecturein-situ resource utilizationsimulated lunar soilthermal analysissintering processlunar soil simulationsintering process optimizationmechanical property evaluationthermal property analysismicrostructural characterizationmechanical property testingmicrostructure analysisphase composition analysislunar constructionthermal expansion stabilitymechanical propertiesthermal conductivitysinteringadditive manufacturing3D printinglunar regolith simulantISRU (In-Situ Resource Utilization)space explorationmaterial sciencesintering techniquesLunar regolith sinteringCeramic phosphor fabricationWCu composite fabricationAl2O3 ceramic sinteringTungsten carbide sinteringPolymeric concrete workabilityBioglass suspension depositionMartian regolith