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{
"count": 92988,
"next": "https://eartharxiv.org/api/keywords/?format=api&limit=100&offset=15700",
"previous": "https://eartharxiv.org/api/keywords/?format=api&limit=100&offset=15500",
"results": [
{
"word": " animal cognition"
},
{
"word": "particle size distribution"
},
{
"word": "ambient aerosols"
},
{
"word": "1 nm aerosols"
},
{
"word": "coastal ground station"
},
{
"word": "lake spray aerosol"
},
{
"word": "field campaign"
},
{
"word": "Lake Michigan"
},
{
"word": "Advertisement call"
},
{
"word": "Endemic"
},
{
"word": "collared frogs"
},
{
"word": "Venezuela"
},
{
"word": "Anura"
},
{
"word": "Dendrobatidae"
},
{
"word": "Bacterioplankton diversity"
},
{
"word": "Antarctic Circumpolar Fronts"
},
{
"word": "16S rRNA sequencing"
},
{
"word": "banding"
},
{
"word": " karst aquifer"
},
{
"word": " climate reconstruction"
},
{
"word": " proxy development"
},
{
"word": " PARAFAC"
},
{
"word": " spectrofluorometer"
},
{
"word": " absorbance"
},
{
"word": " EEM"
},
{
"word": "karst aquifer"
},
{
"word": "climate reconstruction"
},
{
"word": "proxy development"
},
{
"word": "PARAFAC"
},
{
"word": "spectrofluorometer"
},
{
"word": "absorbance"
},
{
"word": "EEM"
},
{
"word": " argillites"
},
{
"word": " compressibility"
},
{
"word": " swelling"
},
{
"word": " anisotropy"
},
{
"word": " discontinuities"
},
{
"word": " hydromechanical coupling"
},
{
"word": " strength"
},
{
"word": " brittleness"
},
{
"word": " progressive failure"
},
{
"word": " underground excavations in situ testing; radioactive waste; temperature effects; Coupled THM processes"
},
{
"word": " atom probe tomography"
},
{
"word": " strain-hardening"
},
{
"word": " nanostructures"
},
{
"word": " crystal-plasticity"
},
{
"word": "atom probe tomography"
},
{
"word": "strain-hardening"
},
{
"word": "nanostructures"
},
{
"word": "crystal-plasticity"
},
{
"word": "bacteriophages"
},
{
"word": "phage-host interaction"
},
{
"word": "phage defense"
},
{
"word": "ice thickness"
},
{
"word": "direct fitness benefits"
},
{
"word": "PINNs"
},
{
"word": " Numerical modeling"
},
{
"word": " Landslides"
},
{
"word": " Shear band"
},
{
"word": "flavonoids"
},
{
"word": " flower color"
},
{
"word": " canonical correlation analysis"
},
{
"word": " pathway evolution"
},
{
"word": " phylo-transcriptomics"
},
{
"word": " Petunieae"
},
{
"word": " Solanaceae"
},
{
"word": " molecular evolution"
},
{
"word": " phenotypic evolution"
},
{
"word": "ice-ocean"
},
{
"word": "internal wave"
},
{
"word": "submarine melt"
},
{
"word": "Aquatic biodiversity"
},
{
"word": "freshwater ecosystem"
},
{
"word": "eDNA"
},
{
"word": "next generation sequencing"
},
{
"word": "Marine reflection seismics"
},
{
"word": "deep base level"
},
{
"word": "meteorite impact"
},
{
"word": "lag dynamics"
},
{
"word": " mountain biodiversity"
},
{
"word": " plant assemblages"
},
{
"word": " shifting isotherms"
},
{
"word": " migration lag"
},
{
"word": " thermophilization"
},
{
"word": "Sustainability Transitions"
},
{
"word": "System Dynamics Modeling"
},
{
"word": "Model Structure/Behavior/Pattern Analysis"
},
{
"word": "Systems Archetype"
},
{
"word": " high-dimensional inference"
},
{
"word": " Markov Chain Monte Carlo"
},
{
"word": " poroelastic model"
},
{
"word": "high-dimensional inference"
},
{
"word": "poroelastic model"
},
{
"word": "Richards equation"
},
{
"word": " shallow-water equations"
},
{
"word": " overtopping flows"
},
{
"word": " finite volume"
},
{
"word": " embankment"
},
{
"word": " numerical simulation."
},
{
"word": "Global model"
}
]
}