[ {
  "@graph" : [ {
    "@id" : "https://w3id.org/np/RAS0ZgDRWQbCddUv_CleyXr8iARBjRL4wDYLdZT0Vrx-A",
    "@type" : [ "http://www.nanopub.org/nschema#Nanopublication" ],
    "http://www.nanopub.org/nschema#hasAssertion" : [ {
      "@id" : "https://w3id.org/np/RAS0ZgDRWQbCddUv_CleyXr8iARBjRL4wDYLdZT0Vrx-A/assertion"
    } ],
    "http://www.nanopub.org/nschema#hasProvenance" : [ {
      "@id" : "https://w3id.org/np/RAS0ZgDRWQbCddUv_CleyXr8iARBjRL4wDYLdZT0Vrx-A/provenance"
    } ],
    "http://www.nanopub.org/nschema#hasPublicationInfo" : [ {
      "@id" : "https://w3id.org/np/RAS0ZgDRWQbCddUv_CleyXr8iARBjRL4wDYLdZT0Vrx-A/pubinfo"
    } ]
  } ],
  "@id" : "https://w3id.org/np/RAS0ZgDRWQbCddUv_CleyXr8iARBjRL4wDYLdZT0Vrx-A/Head"
}, {
  "@graph" : [ {
    "@id" : "http://eurovoc.europa.eu/2919",
    "@type" : [ "http://schema.org/DefinedTerm" ],
    "http://schema.org/description" : [ {
      "@value" : ""
    } ],
    "http://schema.org/name" : [ {
      "@value" : "Environmental research"
    } ]
  }, {
    "@id" : "http://eurovoc.europa.eu/3941",
    "@type" : [ "http://schema.org/DefinedTerm" ],
    "http://schema.org/description" : [ {
      "@value" : ""
    } ],
    "http://schema.org/name" : [ {
      "@value" : "Life sciences"
    } ]
  }, {
    "@id" : "http://eurovoc.europa.eu/3946",
    "@type" : [ "http://schema.org/DefinedTerm" ],
    "http://schema.org/description" : [ {
      "@value" : ""
    } ],
    "http://schema.org/name" : [ {
      "@value" : "Physical sciences"
    } ]
  }, {
    "@id" : "http://eurovoc.europa.eu/3952",
    "@type" : [ "http://schema.org/DefinedTerm" ],
    "http://schema.org/description" : [ {
      "@value" : ""
    } ],
    "http://schema.org/name" : [ {
      "@value" : "Earth sciences"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/-1192778502",
    "@type" : [ "https://w3id.org/contentdesc#Expression" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "grid cell topography"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/-1638434889",
    "@type" : [ "https://w3id.org/contentdesc#Expression" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "reference pressure"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/-1723832340",
    "@type" : [ "https://w3id.org/contentdesc#Domain" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "astronomy"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/-586095033",
    "@type" : [ "https://w3id.org/contentdesc#Domain" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "physics"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/100011496",
    "@type" : [ "https://w3id.org/contentdesc#Concept" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "velocity"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/100011497",
    "@type" : [ "https://w3id.org/contentdesc#Concept" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "temperature"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/100039583",
    "@type" : [ "https://w3id.org/contentdesc#Concept" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "pressure"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/100178005",
    "@type" : [ "https://w3id.org/contentdesc#Concept" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "atmosphere"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/100180631",
    "@type" : [ "https://w3id.org/contentdesc#Concept" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "humidity"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/100207752",
    "@type" : [ "https://w3id.org/contentdesc#Concept" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "latent heat"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/100368677",
    "@type" : [ "https://w3id.org/contentdesc#Concept" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "short wave"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/100686565",
    "@type" : [ "https://w3id.org/contentdesc#Concept" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "prison cell"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/106485375",
    "@type" : [ "https://w3id.org/contentdesc#Concept" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "flux"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/110926444",
    "@type" : [ "https://w3id.org/contentdesc#Concept" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "land"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/159541",
    "@type" : [ "https://w3id.org/contentdesc#Concept" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "simulation"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/194611666",
    "@type" : [ "https://w3id.org/contentdesc#Expression" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "pressure surface"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/249599025",
    "@type" : [ "https://w3id.org/contentdesc#Expression" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "grid cell area"
    } ]
  }, {
    "@id" : "http://w3id.org/ro-id/rohub/model#subject/953464148",
    "@type" : [ "https://w3id.org/contentdesc#Expression" ],
    "http://www.w3.org/2004/02/skos/core#prefLabel" : [ {
      "@value" : "ocean mask"
    } ]
  }, {
    "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/",
    "@type" : [ "http://purl.org/wf4ever/ro#ResearchObject", "http://purl.org/wf4ever/roevo#LiveRO", "http://schema.org/Dataset", "http://w3id.org/ro/earth-science#DataResearchObject", "https://w3id.org/ro/terms/earth-science#DataResearchObject" ],
    "http://schema.org/about" : [ {
      "@id" : "http://eurovoc.europa.eu/2919"
    }, {
      "@id" : "http://eurovoc.europa.eu/3941"
    }, {
      "@id" : "http://eurovoc.europa.eu/3946"
    }, {
      "@id" : "http://eurovoc.europa.eu/3952"
    } ],
    "http://schema.org/author" : [ {
      "@id" : "mailto:chuncheng.guo@rohub.com"
    } ],
    "http://schema.org/contentSize" : [ {
      "@type" : "http://www.w3.org/2001/XMLSchema#integer",
      "@value" : "11342"
    } ],
    "http://schema.org/contentUrl" : [ {
      "@value" : "https://api.rohub.org/api/ros/68fbbd93-8997-48c3-8b90-94073972e340/crate/download/"
    } ],
    "http://schema.org/creator" : [ {
      "@id" : "mailto:georgehadib@gmail.com"
    } ],
    "http://schema.org/dateCreated" : [ {
      "@value" : "2022-03-22 02:52:04.343686+00:00"
    } ],
    "http://schema.org/dateModified" : [ {
      "@value" : "2025-03-05 12:48:07.686809+00:00"
    } ],
    "http://schema.org/datePublished" : [ {
      "@value" : "2022-03-22 02:52:04.343686+00:00"
    } ],
    "http://schema.org/description" : [ {
      "@value" : "This dataset contains 800 years' simulation of the Marine Isotope Stage 3 climate transition, using the NorESM1-F model. Experiment protocol is described in Jansen et al., 2020, A new era of abrupt climate change - perspectives from the past. Data description: case = NBF1850_f19_tn11_test_mis3b_fwf3b_fram; Source = CAM ; Variables =\t\tlev:hybrid level at midpoints (1000*(A+B)) ;\thyam:hybrid A coefficient at layer midpoints ;\thybm:hybrid B coefficient at layer midpoints ;\tilev:hybrid level at interfaces (1000*(A+B)) ;\thyai:hybrid A coefficient at layer interfaces ;\thybi:hybrid B coefficient at layer interfaces ;\tP0:reference pressure ;\ttime:time ;\tdate:current date (YYYYMMDD) ;\tdatesec:current seconds of current date ;\tlat:latitude ;\tlon:longitude ;\tslat:staggered latitude ;\tslon:staggered longitude ;\tw_stag:staggered latitude weights ;\ttime_bnds:time interval endpoints ;\tntrm:spectral truncation parameter M ;\tntrn:spectral truncation parameter N ;\tntrk:spectral truncation parameter K ;\tndbase:base day ;\tnsbase:seconds of base day ;\tnbdate:base date (YYYYMMDD) ;\tnbsec:seconds of base date ;\tmdt:timestep ;\tnlon:number of longitudes ;\twnummax:cutoff Fourier wavenumber ;\tgw:gauss weights ;\tndcur:current day (from base day) ;\tnscur:current seconds of current day ;\tco2vmr:co2 volume mixing ratio ;\tch4vmr:ch4 volume mixing ratio ;\tn2ovmr:n2o volume mixing ratio ;\tf11vmr:f11 volume mixing ratio ;\tf12vmr:f12 volume mixing ratio ;\tsol_tsi:total solar irradiance ;\tnsteph:current timestep ;\tCLDHGH:Vertically-integrated high cloud ;\tCLDLOW:Vertically-integrated low cloud ;\tCLDMED:Vertically-integrated mid-level cloud ;\tCLDTOT:Vertically-integrated total cloud ;\tCLOUD:Cloud fraction ;\tFLDS:Downwelling longwave flux at surface ;\tFLDSC:Clearsky downwelling longwave flux at surface ;\tFLNS:Net longwave flux at surface ;\tFLNSC:Clearsky net longwave flux at surface ;\tFLNT:Net longwave flux at top of model ;\tFLNTC:Clearsky net longwave flux at top of model ;\tFLUT:Upwelling longwave flux at top of model ;\tFLUTC:Clearsky upwelling longwave flux at top of model ;\tFSDS:Downwelling solar flux at surface ;\tFSDSC:Clearsky downwelling solar flux at surface ;\tFSDTOA:Downwelling solar flux at top of atmosphere ;\tFSNS:Net solar flux at surface ;\tFSNSC:Clearsky net solar flux at surface ;\tFSNT:Net solar flux at top of model ;\tFSNTC:Clearsky net solar flux at top of model ;\tFSNTOA:Net solar flux at top of atmosphere ;\tFSNTOAC:Clearsky net solar flux at top of atmosphere ;\tFSUTOA:Upwelling solar flux at top of atmosphere ;\tICEFRAC:Fraction of sfc area covered by sea-ice ;\tLANDFRAC:Fraction of sfc area covered by land ;\tLHFLX:Surface latent heat flux ;\tLWCF:Longwave cloud forcing ;\tOCNFRAC:Fraction of sfc area covered by ocean ;\tOMEGA:Vertical velocity (pressure) ;\tOMEGA500:Vertical velocity at 500 mbar pressure surface ;\tOMEGA850:Vertical velocity at 850 mbar pressure surface ;\tPBLH:PBL height ;\tPRECC:Convective precipitation rate (liq + ice) ;\tPRECL:Large-scale (stable) precipitation rate (liq + ice) ;\tPRECT:Total (convective and large-scale) precipitation rate (liq + ice) ;\tPS:Surface pressure ;\tPSL:Sea level pressure ;\tQ:Specific humidity ;\tQFLX:Surface water flux ;\tQREFHT:Reference height humidity ;\tRELHUM:Relative humidity ;\tRHREFHT:Reference height relative humidity ;\tSHFLX:Surface sensible heat flux ;\tSNOWHICE:Water equivalent snow depth ;\tSNOWHLND:Water equivalent snow depth ;\tSOLIN:Solar insolation ;\tSOLLD:Solar downward near infrared diffuse to surface ;\tSOLSD:Solar downward visible diffuse to surface ;\tSRFRAD:Net radiative flux at surface ;\tSWCF:Shortwave cloud forcing ;\tT:Temperature ;\tT1000:Temperature at 1000 mbar pressure surface ;\tT200:Temperature at 200 mbar pressure surface ;\tT500:Temperature at 500 mbar pressure surface ;\tT700:Temperature at 700 mbar pressure surface ;\tT850:Temperature at 850 mbar pressure surface ;\tTAUX:Zonal surface stress ;\tTAUY:Meridional surface stress ;\tTGCLDLWP:Total grid-box cloud liquid water path ;\tTMQ:Total (vertically integrated) precipitatable water ;\tTREFHT:Reference height temperature ;\tTS:Surface temperature (radiative) ;\tTSMN:Minimum surface temperature over output period ;\tTSMX:Maximum surface temperature over output period ;\tU:Zonal wind ;\tU10:10m wind speed ;\tU200:Zonal wind at 200 mbar pressure surface ;\tU850:Zonal wind at 850 mbar pressure surface ;\tV:Meridional wind ;\tV200:Meridional wind at 200 mbar pressure surface ;\tV850:Meridional wind at 850 mbar pressure surface ;\tZ050:Geopotential Z at 50 mbar pressure surface ;\tZ100:Geopotential Z at 100 mbar pressure surface ;\tZ200:Geopotential Z at 200 mbar pressure surface ;\tZ3:Geopotential Height (above sea level) ;\tZ300:Geopotential Z at 300 mbar pressure surface ;\tZ500:Geopotential Z at 500 mbar pressure surface ;\tZ700:Geopotential Z at 700 mbar pressure surface ;\tSource = MICOM ; Variables =\t\ttime:time ;\tsigma:Potential density ;\tdepth:z level ;\tsigmx:Mixed layer density ;\tubaro:Barotropic velocity x-component ;\tvbaro:Barotropic velocity y-component ;\tsealv:Sea level ;\tfice:Ice concentration ;\tswa:Short-wave heat flux ;\tnsf:Non-solar heat flux ;\thmltfz:Heat flux due to melting/freezing ;\thflx:Heat flux received by ocean ;\tlip:Liquid precipitation ;\tsop:Solid precipitation ;\teva:Evaporation ;\tfmltfz:Fresh water flux due to melting/freezing ;\trnf:Liquid runoff ;\trfi:Frozen runoff ;\tsflx:Salt flux received by ocean ;\tbflx:Brine flux ;\tztx:Wind stress x-component ;\tmty:Wind stress y-component ;\ttaux:Momentum flux received by ocean x-component ;\ttauy:Momentum flux received by ocean y-component ;\tustar:Friction velocity ;\tabswnd:Absolute wind speed ;\tsfl:Salt flux ;\tmld:Mixed layer depth ;\tmaxmld:Maximum mixed layer depth ;\tbrnpd:Brine plume depth ;\tsst:Ocean surface temperature ;\tsss:Ocean surface salinity ;\tmxlu:Mixed layer velocity x-component ;\tmxlv:Mixed layer velocity y-component ;\tSource = CLM ; Variables =\t\tlevgrnd:coordinate soil levels ;\tlevlak:coordinate lake levels ;\tedgen:northern edge of surface grid ;\tedgee:eastern edge of surface grid ;\tedges:southern edge of surface grid ;\tedgew:western edge of surface grid ;\ttime:time ;\tmcdate:current date (YYYYMMDD) ;\tmcsec:current seconds of current date ;\tmdcur:current day (from base day) ;\tmscur:current seconds of current day ;\tnstep:time step ;\ttime_bounds:history time interval endpoints ;\tlon:coordinate longitude ;\tlat:coordinate latitude ;\tlonatm:atm coordinate longitude ;\tlatatm:atm coordinate latitude ;\tlonrof:runoff coordinate longitude ;\tlatrof:runoff coordinate latitude ;\tlongxy:longitude ;\tlatixy:latitude ;\tarea:grid cell areas ;\tareaupsc:normalized grid cell areas related to upscaling ;\ttopo:grid cell topography ;\ttopodnsc:normalized grid cell topography related to downscaling ;\tlandfrac:land fraction ;\tlandmask:land/ocean mask (0.=ocean and 1.=land) ;\tpftmask:pft real/fake mask (0.=fake and 1.=real) ;\tindxupsc:upscaling atm global grid index ;\tlongxyatm:atm longitude ;\tlatixyatm:atm latitude ;\tareaatm:atm grid cell areas ;\tZSOI:soil depth ;\tDZSOI:soil thickness ;\tWATSAT:saturated soil water content (porosity) ;\tSUCSAT:saturated soil matric potential ;\tBSW:slope of soil water retention curve ;\tHKSAT:saturated hydraulic conductivity ;\tFSNO:fraction of ground covered by snow ;\tSNOWDP:snow height ;\tSOILWATER_10CM:soil liquid water + ice in top 10cm of soil ;\tSource = CICE ; Variables =\t\ttime:model time ;\ttime_bounds:boundaries for time-averaging interval ;\tTLON:T grid center longitude ;\tTLAT:T grid center latitude ;\tULON:U grid center longitude ;\tULAT:U grid center latitude ;\ttarea:area of T grid cells ;\tANGLE:angle grid makes with latitude line on U grid ;\thi:grid cell mean ice thickness ;\ths:grid cell mean snow thickness ;\tfs:grid cell mean snow fraction ;\taice:ice area  (aggregate) ;\tuvel:ice velocity (x) ;\tvvel:ice velocity (y) ;\ttransix:ice mass transport (x) on East side ;\ttransiy:ice mass transport (y) on North side ;\tcongel:congelation ice growth ;\tfrazil:frazil ice growth ;\tmeltt:top ice melt ;\tmeltb:basal ice melt ;\tmeltl:lateral ice melt ;\tfresh_ai:freshwtr flx ice to ocn ;\tfsalt_ai:salt flux ice to ocean ;\tScientific Publication: Jansen et al., 2020,Past perspectives on the present era of abrupt Arctic climate change, LINK: http://doi.org/10.1038/s41558-020-0860-7"
    } ],
    "http://schema.org/encodingFormat" : [ {
      "@value" : "application/ld+json"
    } ],
    "http://schema.org/hasPart" : [ {
      "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/folders/723cfff9-8cbf-483c-82a0-bef5b7a6f4a3"
    }, {
      "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/folders/9a41d312-6ed3-43c2-8d1e-a13db7fd1d93"
    }, {
      "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/folders/bd791eba-c0af-40bd-b75f-1c65d15a3417"
    }, {
      "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/folders/d8a77627-7010-49c0-88ba-b7dd0b21090c"
    } ],
    "http://schema.org/identifier" : [ {
      "@value" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340"
    } ],
    "http://schema.org/license" : [ {
      "@id" : "https://choosealicense.com/no-permission/"
    } ],
    "http://schema.org/name" : [ {
      "@value" : "NorESM1-F simulation of the Marine Isotope Stage 3 stadial-to-interstadial transition"
    } ],
    "http://w3id.org/ro-id/rohub/model#creation_mode" : [ {
      "@value" : "MANUAL"
    } ],
    "https://www.w3.org/ns/iana/link-relations/relation#cite-as" : [ {
      "@value" : "Chuncheng Guo. \"NorESM1-F simulation of the Marine Isotope Stage 3 stadial-to-interstadial transition.\" ROHub. Mar 22 ,2022. https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340."
    } ]
  }, {
    "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/#enrichment_service-account-enrichment",
    "@type" : [ "http://xmlns.com/foaf/0.1/Agent" ],
    "http://schema.org/name" : [ {
      "@value" : "service-account-enrichment"
    } ]
  }, {
    "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/folders/723cfff9-8cbf-483c-82a0-bef5b7a6f4a3",
    "@type" : [ "http://purl.org/wf4ever/wf4ever#Folder", "http://schema.org/Dataset" ],
    "http://schema.org/name" : [ {
      "@value" : "raw data"
    } ]
  }, {
    "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/folders/9a41d312-6ed3-43c2-8d1e-a13db7fd1d93",
    "@type" : [ "http://purl.org/wf4ever/wf4ever#Folder", "http://schema.org/Dataset" ],
    "http://schema.org/name" : [ {
      "@value" : "biblio"
    } ]
  }, {
    "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/folders/bd791eba-c0af-40bd-b75f-1c65d15a3417",
    "@type" : [ "http://purl.org/wf4ever/wf4ever#Folder", "http://schema.org/Dataset" ],
    "http://schema.org/hasPart" : [ {
      "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/resources/1f1c30fd-56ad-4dbd-b456-2f66f525b74b"
    } ],
    "http://schema.org/name" : [ {
      "@value" : "data"
    } ]
  }, {
    "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/folders/d8a77627-7010-49c0-88ba-b7dd0b21090c",
    "@type" : [ "http://purl.org/wf4ever/wf4ever#Folder", "http://schema.org/Dataset" ],
    "http://schema.org/name" : [ {
      "@value" : "metadata"
    } ]
  }, {
    "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/resources/1f1c30fd-56ad-4dbd-b456-2f66f525b74b",
    "@type" : [ "http://purl.org/wf4ever/wf4ever#Dataset", "http://purl.org/wf4ever/wf4ever#Resource", "http://schema.org/MediaObject" ],
    "http://schema.org/author" : [ {
      "@id" : "mailto:georgehadib@gmail.com"
    } ],
    "http://schema.org/contentUrl" : [ {
      "@value" : "https://archive.sigma2.no/pages/public/datasetDetail.jsf?id=10.11582/2020.00006"
    } ],
    "http://schema.org/creator" : [ {
      "@id" : "mailto:georgehadib@gmail.com"
    } ],
    "http://schema.org/dateCreated" : [ {
      "@value" : "2022-03-22 02:52:15.583800+00:00"
    } ],
    "http://schema.org/dateModified" : [ {
      "@value" : "2022-03-22 02:52:20.390738+00:00"
    } ],
    "http://schema.org/description" : [ {
      "@value" : "This dataset contains 800 years' simulation of the Marine Isotope Stage 3 climate transition, using the NorESM1-F model. Experiment protocol is described in Jansen et al., 2020, A new era of abrupt climate change - perspectives from the past. Data description: case = NBF1850_f19_tn11_test_mis3b_fwf3b_fram; Source = CAM ; Variables =\t\tlev:hybrid level at midpoints (1000*(A+B)) ;\thyam:hybrid A coefficient at layer midpoints ;\thybm:hybrid B coefficient at layer midpoints ;\tilev:hybrid level at interfaces (1000*(A+B)) ;\thyai:hybrid A coefficient at layer interfaces ;\thybi:hybrid B coefficient at layer interfaces ;\tP0:reference pressure ;\ttime:time ;\tdate:current date (YYYYMMDD) ;\tdatesec:current seconds of current date ;\tlat:latitude ;\tlon:longitude ;\tslat:staggered latitude ;\tslon:staggered longitude ;\tw_stag:staggered latitude weights ;\ttime_bnds:time interval endpoints ;\tntrm:spectral truncation parameter M ;\tntrn:spectral truncation parameter N ;\tntrk:spectral truncation parameter K ;\tndbase:base day ;\tnsbase:seconds of base day ;\tnbdate:base date (YYYYMMDD) ;\tnbsec:seconds of base date ;\tmdt:timestep ;\tnlon:number of longitudes ;\twnummax:cutoff Fourier wavenumber ;\tgw:gauss weights ;\tndcur:current day (from base day) ;\tnscur:current seconds of current day ;\tco2vmr:co2 volume mixing ratio ;\tch4vmr:ch4 volume mixing ratio ;\tn2ovmr:n2o volume mixing ratio ;\tf11vmr:f11 volume mixing ratio ;\tf12vmr:f12 volume mixing ratio ;\tsol_tsi:total solar irradiance ;\tnsteph:current timestep ;\tCLDHGH:Vertically-integrated high cloud ;\tCLDLOW:Vertically-integrated low cloud ;\tCLDMED:Vertically-integrated mid-level cloud ;\tCLDTOT:Vertically-integrated total cloud ;\tCLOUD:Cloud fraction ;\tFLDS:Downwelling longwave flux at surface ;\tFLDSC:Clearsky downwelling longwave flux at surface ;\tFLNS:Net longwave flux at surface ;\tFLNSC:Clearsky net longwave flux at surface ;\tFLNT:Net longwave flux at top of model ;\tFLNTC:Clearsky net longwave flux at top of model ;\tFLUT:Upwelling longwave flux at top of model ;\tFLUTC:Clearsky upwelling longwave flux at top of model ;\tFSDS:Downwelling solar flux at surface ;\tFSDSC:Clearsky downwelling solar flux at surface ;\tFSDTOA:Downwelling solar flux at top of atmosphere ;\tFSNS:Net solar flux at surface ;\tFSNSC:Clearsky net solar flux at surface ;\tFSNT:Net solar flux at top of model ;\tFSNTC:Clearsky net solar flux at top of model ;\tFSNTOA:Net solar flux at top of atmosphere ;\tFSNTOAC:Clearsky net solar flux at top of atmosphere ;\tFSUTOA:Upwelling solar flux at top of atmosphere ;\tICEFRAC:Fraction of sfc area covered by sea-ice ;\tLANDFRAC:Fraction of sfc area covered by land ;\tLHFLX:Surface latent heat flux ;\tLWCF:Longwave cloud forcing ;\tOCNFRAC:Fraction of sfc area covered by ocean ;\tOMEGA:Vertical velocity (pressure) ;\tOMEGA500:Vertical velocity at 500 mbar pressure surface ;\tOMEGA850:Vertical velocity at 850 mbar pressure surface ;\tPBLH:PBL height ;\tPRECC:Convective precipitation rate (liq + ice) ;\tPRECL:Large-scale (stable) precipitation rate (liq + ice) ;\tPRECT:Total (convective and large-scale) precipitation rate (liq + ice) ;\tPS:Surface pressure ;\tPSL:Sea level pressure ;\tQ:Specific humidity ;\tQFLX:Surface water flux ;\tQREFHT:Reference height humidity ;\tRELHUM:Relative humidity ;\tRHREFHT:Reference height relative humidity ;\tSHFLX:Surface sensible heat flux ;\tSNOWHICE:Water equivalent snow depth ;\tSNOWHLND:Water equivalent snow depth ;\tSOLIN:Solar insolation ;\tSOLLD:Solar downward near infrared diffuse to surface ;\tSOLSD:Solar downward visible diffuse to surface ;\tSRFRAD:Net radiative flux at surface ;\tSWCF:Shortwave cloud forcing ;\tT:Temperature ;\tT1000:Temperature at 1000 mbar pressure surface ;\tT200:Temperature at 200 mbar pressure surface ;\tT500:Temperature at 500 mbar pressure surface ;\tT700:Temperature at 700 mbar pressure surface ;\tT850:Temperature at 850 mbar pressure surface ;\tTAUX:Zonal surface stress ;\tTAUY:Meridional surface stress ;\tTGCLDLWP:Total grid-box cloud liquid water path ;\tTMQ:Total (vertically integrated) precipitatable water ;\tTREFHT:Reference height temperature ;\tTS:Surface temperature (radiative) ;\tTSMN:Minimum surface temperature over output period ;\tTSMX:Maximum surface temperature over output period ;\tU:Zonal wind ;\tU10:10m wind speed ;\tU200:Zonal wind at 200 mbar pressure surface ;\tU850:Zonal wind at 850 mbar pressure surface ;\tV:Meridional wind ;\tV200:Meridional wind at 200 mbar pressure surface ;\tV850:Meridional wind at 850 mbar pressure surface ;\tZ050:Geopotential Z at 50 mbar pressure surface ;\tZ100:Geopotential Z at 100 mbar pressure surface ;\tZ200:Geopotential Z at 200 mbar pressure surface ;\tZ3:Geopotential Height (above sea level) ;\tZ300:Geopotential Z at 300 mbar pressure surface ;\tZ500:Geopotential Z at 500 mbar pressure surface ;\tZ700:Geopotential Z at 700 mbar pressure surface ;\tSource = MICOM ; Variables =\t\ttime:time ;\tsigma:Potential density ;\tdepth:z level ;\tsigmx:Mixed layer density ;\tubaro:Barotropic velocity x-component ;\tvbaro:Barotropic velocity y-component ;\tsealv:Sea level ;\tfice:Ice concentration ;\tswa:Short-wave heat flux ;\tnsf:Non-solar heat flux ;\thmltfz:Heat flux due to melting/freezing ;\thflx:Heat flux received by ocean ;\tlip:Liquid precipitation ;\tsop:Solid precipitation ;\teva:Evaporation ;\tfmltfz:Fresh water flux due to melting/freezing ;\trnf:Liquid runoff ;\trfi:Frozen runoff ;\tsflx:Salt flux received by ocean ;\tbflx:Brine flux ;\tztx:Wind stress x-component ;\tmty:Wind stress y-component ;\ttaux:Momentum flux received by ocean x-component ;\ttauy:Momentum flux received by ocean y-component ;\tustar:Friction velocity ;\tabswnd:Absolute wind speed ;\tsfl:Salt flux ;\tmld:Mixed layer depth ;\tmaxmld:Maximum mixed layer depth ;\tbrnpd:Brine plume depth ;\tsst:Ocean surface temperature ;\tsss:Ocean surface salinity ;\tmxlu:Mixed layer velocity x-component ;\tmxlv:Mixed layer velocity y-component ;\tSource = CLM ; Variables =\t\tlevgrnd:coordinate soil levels ;\tlevlak:coordinate lake levels ;\tedgen:northern edge of surface grid ;\tedgee:eastern edge of surface grid ;\tedges:southern edge of surface grid ;\tedgew:western edge of surface grid ;\ttime:time ;\tmcdate:current date (YYYYMMDD) ;\tmcsec:current seconds of current date ;\tmdcur:current day (from base day) ;\tmscur:current seconds of current day ;\tnstep:time step ;\ttime_bounds:history time interval endpoints ;\tlon:coordinate longitude ;\tlat:coordinate latitude ;\tlonatm:atm coordinate longitude ;\tlatatm:atm coordinate latitude ;\tlonrof:runoff coordinate longitude ;\tlatrof:runoff coordinate latitude ;\tlongxy:longitude ;\tlatixy:latitude ;\tarea:grid cell areas ;\tareaupsc:normalized grid cell areas related to upscaling ;\ttopo:grid cell topography ;\ttopodnsc:normalized grid cell topography related to downscaling ;\tlandfrac:land fraction ;\tlandmask:land/ocean mask (0.=ocean and 1.=land) ;\tpftmask:pft real/fake mask (0.=fake and 1.=real) ;\tindxupsc:upscaling atm global grid index ;\tlongxyatm:atm longitude ;\tlatixyatm:atm latitude ;\tareaatm:atm grid cell areas ;\tZSOI:soil depth ;\tDZSOI:soil thickness ;\tWATSAT:saturated soil water content (porosity) ;\tSUCSAT:saturated soil matric potential ;\tBSW:slope of soil water retention curve ;\tHKSAT:saturated hydraulic conductivity ;\tFSNO:fraction of ground covered by snow ;\tSNOWDP:snow height ;\tSOILWATER_10CM:soil liquid water + ice in top 10cm of soil ;\tSource = CICE ; Variables =\t\ttime:model time ;\ttime_bounds:boundaries for time-averaging interval ;\tTLON:T grid center longitude ;\tTLAT:T grid center latitude ;\tULON:U grid center longitude ;\tULAT:U grid center latitude ;\ttarea:area of T grid cells ;\tANGLE:angle grid makes with latitude line on U grid ;\thi:grid cell mean ice thickness ;\ths:grid cell mean snow thickness ;\tfs:grid cell mean snow fraction ;\taice:ice area  (aggregate) ;\tuvel:ice velocity (x) ;\tvvel:ice velocity (y) ;\ttransix:ice mass transport (x) on East side ;\ttransiy:ice mass transport (y) on North side ;\tcongel:congelation ice growth ;\tfrazil:frazil ice growth ;\tmeltt:top ice melt ;\tmeltb:basal ice melt ;\tmeltl:lateral ice melt ;\tfresh_ai:freshwtr flx ice to ocn ;\tfsalt_ai:salt flux ice to ocean ;\tScientific Publication: Jansen et al., 2020,Past perspectives on the present era of abrupt Arctic climate change, <a href=\"http://doi.org/10.1038/s41558-020-0860-7\" class=\"linkified\" target=\"_blank\">LINK</a>"
    } ],
    "http://schema.org/license" : [ {
      "@id" : "https://choosealicense.com/no-permission/"
    } ],
    "http://schema.org/name" : [ {
      "@value" : "NorESM1-F simulation of the Marine Isotope Stage 3 stadial-to-interstadial transition"
    } ],
    "http://schema.org/sdDatePublished" : [ {
      "@value" : "2022-03-22 02:52:15.583800+00:00"
    } ]
  }, {
    "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/ro-crate-metadata.json",
    "@type" : [ "http://schema.org/CreativeWork" ],
    "http://purl.org/dc/terms/conformsTo" : [ {
      "@id" : "https://w3id.org/ro/crate/1.1"
    } ],
    "http://schema.org/about" : [ {
      "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/"
    } ]
  }, {
    "@id" : "mailto:chuncheng.guo@rohub.com",
    "@type" : [ "http://xmlns.com/foaf/0.1/Agent" ],
    "http://schema.org/email" : [ {
      "@value" : "chuncheng.guo@rohub.com"
    } ],
    "http://schema.org/name" : [ {
      "@value" : "Chuncheng Guo"
    } ]
  }, {
    "@id" : "mailto:georgehadib@gmail.com",
    "@type" : [ "http://xmlns.com/foaf/0.1/Agent" ],
    "http://schema.org/name" : [ {
      "@value" : "Geo H."
    } ]
  } ],
  "@id" : "https://w3id.org/np/RAS0ZgDRWQbCddUv_CleyXr8iARBjRL4wDYLdZT0Vrx-A/assertion"
}, {
  "@graph" : [ {
    "@id" : "https://w3id.org/np/RAS0ZgDRWQbCddUv_CleyXr8iARBjRL4wDYLdZT0Vrx-A/assertion",
    "http://www.w3.org/ns/prov#wasDerivedFrom" : [ {
      "@id" : "https://api.rohub.org/api/ros/68fbbd93-8997-48c3-8b90-94073972e340/crate/download/ro-crate-metadata.json"
    } ]
  } ],
  "@id" : "https://w3id.org/np/RAS0ZgDRWQbCddUv_CleyXr8iARBjRL4wDYLdZT0Vrx-A/provenance"
}, {
  "@graph" : [ {
    "@id" : "https://w3id.org/np/RAS0ZgDRWQbCddUv_CleyXr8iARBjRL4wDYLdZT0Vrx-A",
    "@type" : [ "http://purl.org/nanopub/x/RoCrateNanopub" ],
    "http://purl.org/dc/terms/created" : [ {
      "@type" : "http://www.w3.org/2001/XMLSchema#dateTime",
      "@value" : "2026-03-03T16:13:07.681+01:00"
    } ],
    "http://purl.org/dc/terms/creator" : [ {
      "@id" : "https://w3id.org/kpxl/gen/terms/RoCrateBot"
    } ],
    "http://purl.org/nanopub/x/introduces" : [ {
      "@id" : "https://w3id.org/ro-id/68fbbd93-8997-48c3-8b90-94073972e340/"
    } ],
    "http://www.w3.org/2000/01/rdf-schema#label" : [ {
      "@value" : "NorESM1-F simulation of the Marine Isotope Stage 3 stadial-to-interstadial transition"
    } ]
  }, {
    "@id" : "https://w3id.org/np/RAS0ZgDRWQbCddUv_CleyXr8iARBjRL4wDYLdZT0Vrx-A/sig",
    "http://purl.org/nanopub/x/hasAlgorithm" : [ {
      "@value" : "RSA"
    } ],
    "http://purl.org/nanopub/x/hasPublicKey" : [ {
      "@value" : "MIIBIjANBgkqhkiG9w0BAQEFAAOCAQ8AMIIBCgKCAQEAxszSDYX5tuCSkP7UiCtftYPFNQVTjgNu0I5fwdML2DLRDlp0xzmsQXRk8oHuvwGvG1aMjj6cpUqO+0rz2Sg/wvHOgUpkRH8VJXvmlkhafMLCMtUtk5JIx7e+fkzCby+fnmD7kMkGLrT+OaExWwEDmNlCAt0TPKcHSdwsjso2isXjtAsGevyCMke8ufnFYpjs746JES1eNzVnHnn2Kp/lqcm60GM+J8dLgRZp7fX0anW098xhKym6+xXFzqeju0vYRIHBPerv+r7skWxwk+a7Sd8msqVeYEv6NTqnyWvyWb6Yh8cvj04N6qm/T6C5FUPLQhzSaQgMVMU6yLqjPuu9DwIDAQAB"
    } ],
    "http://purl.org/nanopub/x/hasSignature" : [ {
      "@value" : "uQGrGVl34xDWlPzIFO0dHcQNRVXd+zd7rUwshZpGJXo6bK5HImY/VOvTOt6Qy3bF690mPTv5T2EJ+ndMWWFEf2JdL+bt+bTkCKa9w9G2vdWrpgpcuB+GhHSUGKUs7wvGM4jGiQlGkDv23CEod53vv4PbYt3ZC2tI5Uwoq5+2sp909kREqfi9RQt+BxY2ygcolPODuutwYEoQq3KCeod00DMl5em/n2ES0a7GT/tlipxalHF/qbEYL962xTX3mXVZMv83jt3xJPy6VUKfA4WxchxCGF1vuD88QPWqlTiJ1W9K/RpgGvm+A301y6SJhTmIN4TZ5bdawtyPRXjMBEldUQ=="
    } ],
    "http://purl.org/nanopub/x/hasSignatureTarget" : [ {
      "@id" : "https://w3id.org/np/RAS0ZgDRWQbCddUv_CleyXr8iARBjRL4wDYLdZT0Vrx-A"
    } ],
    "http://purl.org/nanopub/x/signedBy" : [ {
      "@id" : "https://w3id.org/kpxl/gen/terms/RoCrateBot"
    } ]
  } ],
  "@id" : "https://w3id.org/np/RAS0ZgDRWQbCddUv_CleyXr8iARBjRL4wDYLdZT0Vrx-A/pubinfo"
} ]