Enhanced in-situ utilization of lunar simulant for fibre-reinforced high-performance concrete: Mechanical properties and cost-effectiveness for lunar applications

R. Shao, C. Wu, J. Li | 2025 | Journal of Materials Research and Technology

DOI 10.1016/j.jmrt.2025.03.047

Review state

Needs reviewShown data

Last reviewed

Not reviewed yet

Last approved reanalysis

No approved reanalysis yet

Summary

This paper explores the use of lunar simulant in fibre-reinforced high-performance concrete (LHPC) for lunar construction. It evaluates mechanical properties, mass-strength efficiency, and cost-effectiveness of LHPC with various fibre types. The study highlights the benefits of hybrid steel-polypropylene fibres in enhancing structural integrity and reducing transportation costs. The paper presents a study on the development of fiber-reinforced concrete using lunar regolith simulant as a base material. The research is supported by the Australian Research Council (ARC) under grant DP210101100. The study involves experimental work conducted at UTS Tech Lab with assistance from staff and PhD students. The paper is published in the journal 'Materials Research Bulletin' (ISSN 0025-5416) under the title 'Development of Fiber-Reinforced Concrete Using Lunar Regolith Simulant as a Base Material'. The provided text appears to be a list of image URLs and metadata, likely from a scientific or technical paper hosted on a platform like ScienceDirect or similar. Each entry includes a URL, file type (e.g., JPEG, GIF), and dimensions. The URLs are structured with a common base (`https://s3-eu-west-

Connected extracted records

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

Used simulants

ALS

Mare simulant

Needs review

95% confidencepage 10

Returned samples

No returned samples extracted yet.

Experiments and measurements

mechanical properties evaluation

mechanical testing

Needs review

bending tests, structural integrity assessment, microstructural analysis, cost-benefit analysis, transportation cost evaluation, material performance testing, fibre reinforcement effectiveness testing, structural load capacity testing90% confidencepage 1

material performance testing

mechanical testing

Needs review

microstructural analysis

material analysis

Needs review

Fibre Reinforcement Study

Mechanical Properties

Needs review

Workability Testing, Unit Weight Measurement, Microstructural Analysis, Compressive and Flexural Strength Testing95% confidencepage 9

Mass-Strength Efficiency Analysis

Logistical Efficiency

Needs review

Cost-Benefit Analysis, Transportation Cost Estimation95% confidencepage 9

Geopolymer Production Study

Material Synthesis

Needs review

Curing Tests, Strength Evaluation, Thermal Analysis95% confidencepage 10

flexural strength measurement

mechanical testing

Needs review

Differential scanning calorimetry (DSC), compressive strength measurement, tensile strength measurement, toughness measurement, impact resistance measurement, fatigue resistance measurement, microstructure analysis, mass-strength efficiency evaluation100% confidencepage 1

Uniaxial compression test

Mechanical | Mechanical strength evaluation

Needs review

ASTM C109 /C109 M100% confidencepage 13

Measured properties

mechanical properties

evaluated through bending tests and structural integrity assessment

Needs review

mechanical90% confidencepage 1

material performance

tested through material performance testing and microstructural analysis

Needs review

material90% confidencepage 1

microstructural analysis

conducted through microstructural analysis and material performance testing

Needs review

material90% confidencepage 1

Platform

ScienceDirect or similar academic platform

Needs review

Source90% confidencepage 5

Compressive strength

125.2 MPa

Needs review

mechanical100% confidencepage 1

Flexural Strength

11.5 MPa

Needs review

Mechanical95% confidencepage 9

Thermal Stability

High

Needs review

Material95% confidencepage 10

flexural strength

3.1 MPa

Needs review

mechanical100% confidencepage 1

Methods and applications

Methods

bending testsstructural integrity assessmentmicrostructural analysiscost-benefit analysistransportation cost evaluationmaterial performance testingfibre reinforcement effectiveness testingstructural load capacity testingUse of lunar regolith simulant as a base materialIncorporation of fiber reinforcementMechanical testing (compression, flexural, tensile)Microstructural analysis (SEM, XRD)Durability testing (freeze-thaw, sulfate attack)Optimization of mix proportionsEvaluation of mechanical and physical propertiesRegular Expression Matching for URL ParsingString Tokenization for Metadata ExtractionKeyword Matching for Image Resolution ClassificationPattern Recognition for File Format IdentificationSlump testUnit weight testCompressive strength testFlexural strength testToughness testMass-strength efficiency testDIC (Digital Image Correlation) testWorkability TestingUnit Weight MeasurementCompressive and Flexural Strength TestingTransportation Cost EstimationCuring TestsStrength EvaluationThermal AnalysisSuperplasticizer TestingExtrudability Assessmentdry blendingalkali activationgeopolymerizationmicrostructure analysismechanical testingmass-strength efficiency evaluationcompressive load measurementdigital image correlation (DIC) systemload-displacement measurementsstress-strain analysisstress-strain curvesultimate compressive strengthsDIC systemfailure patternscrack propagationload-bearing capacityductilitytoughnessstatic MOEcuring durationscompressive strengthfibre contenthybrid reinforcementmicrostructurecrack bridgingflexural strengthvolume fractionstrength gain ratecrack distributioncrack widthssurface spallingLoad-midspan displacement relationshipsArea beneath the load-deflection curvePeak load (P p) and cracking load (P cr)Deflection at cracking load (cr)Deflection-hardening responseEnergy absorptionFibre distribution impactMaterial and energy efficiencyFour-point bending testsScanning electron microscope (SEM) analysisSEM-EDS microanalysisequation-based calculationcomparative analysiscuring duration analysis

Applications

lunar constructionspace explorationhigh-performance concretefibre-reinforced materialsstructural engineeringmaterial scienceeconomic evaluationtransportation logisticsSpace habitat developmentPlanetary surface engineeringAdvanced materials for extreme environmentsAcademic ResearchDigital Library ManagementImage ProcessingData AnalysisConcrete productionLunar Base ConstructionSustainable Space HabitatsIn-Situ Resource Utilization (ISRU)3D-Printed Lunar Structureshigh-corrosion environmentshigh-strength material developmentlunar simulant-based concretefibre-reinforced high-performance concretemechanical propertiescost-effectivenessductilitytoughnessflexural strengthcompressive strengthhybrid reinforcementHigh durability and crack resistance scenariosEnergy absorption in structural materialsLunar regolith utilizationFibre-reinforced concreteLunar habitat constructionlunar habitatsBenchmarking and comparisonConstruction and infrastructureOxygen extractionin-situ resource utilizationextraterrestrial structuresconcrete production on the moongeopolymer concreteMechanical testing of concrete and mortarWorkability testing of cement mortarReview of fiber reinforcement effects on geopolymer compositesWorkability analysis of fiber-reinforced mortar