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HIT-L-1 | Lunar Simulant Atlas

HIT-L-1

lunar regolith simulant

Overview Literature Properties Methods & measurements Applications

Applications

6

Unspecified application

2 sources for this simulant

23 methods

Thermokinetic and rheological characteristics analysischaracterization1 source for this simulantFibers drawn out from melting lunar regolith simulant: An appealing approach to support the lunar in-situ resource utilization

Annealing temperature determinationmaterial processing1 source for this simulantFibers drawn out from melting lunar regolith simulant: An appealing approach to support the lunar in-situ resource utilization

Geopolymerisation reaction analysis

Chemical reaction analysis

1 source for this simulant

Coupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Mechanical property analysisMechanical performance evaluation1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Compressive strength evaluationMechanical performance evaluation1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Product formation analysisPhase assemblage analysis1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Pore solution analysisChemical composition analysis1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Composition-performance correlation analysisMaterial property correlation1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Data availabilityData accessibility1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Preparation technique analysisMaterial preparation analysis1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Mechanical property optimizationMechanical performance evaluation1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Environmental impact analysisEnvironmental performance evaluation1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Geopolymer preparation technique optimizationMaterial preparation analysis1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Thermodynamic modellingThermodynamic analysis1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

XRD analysismineral composition1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Raman spectroscopychemical bonds1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

compressive strength and slurry fluidity testperformance evaluation1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

thermodynamic calculationsnumerical simulation1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

isothermal calorimetrykinetic analysis1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

ICP-OESelemental analysis1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Isothermal calorimetryreaction kinetics1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

thermogravimetric analysis (TGA)thermal analysis1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

pore solution analysissolution characterization1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Benchmarking and comparison

1 source for this simulant

1 method

X-ray diffractionMineralogical characterization | Benchmarking and comparison1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Biology and plant growth

1 source for this simulant

1 method

Leachate chemistryChemical extraction | Biology and plant growth1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Construction and infrastructure

1 source for this simulant

2 methods

Compressive strength testingMechanical testing | Construction and infrastructure1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Geopolymerization / alkali activationBinder chemistry | Construction and infrastructure1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Lunar regolith simulant geopolymerization reaction

1 source for this simulant

1 method

Coupling thermodynamic modelling with experimental studyThermodynamic and experimental analysis | Lunar regolith simulant geopolymerization reaction1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers

Thermal processing

1 source for this simulant

1 method

Thermogravimetric / differential thermal analysisThermal characterization | Thermal processing1 source for this simulantCoupling thermodynamic modelling with experimental study to reveal the evolutionary relationship of pore solutions, products, and compressive strength for lunar regolith simulant geopolymers