quantitykind:ThermodynamicEntropy

URI: http://qudt.org/vocab/quantitykind/ThermodynamicEntropy

Type
Description

Thermodynamic Entropy is a measure of the unavailability of a system’s energy to do work. It is a measure of the randomness of molecules in a system and is central to the second law of thermodynamics and the fundamental thermodynamic relation, which deal with physical processes and whether they occur spontaneously. The dimensions of entropy are energy divided by temperature, which is the same as the dimensions of Boltzmann's constant ($kB$) and heat capacity. The SI unit of entropy is $joule\ per\ kelvin$. [Wikipedia]

Properties
qudt:applicableUnit
skos:broader
qudt:hasDimensionVector
qudt:isoNormativeReference
http://www.iso.org/iso/catalogue_detail?csnumber=31890
rdf:type
Annotations
dcterms:description
Thermodynamic Entropy is a measure of the unavailability of a system’s energy to do work. It is a measure of the randomness of molecules in a system and is central to the second law of thermodynamics and the fundamental thermodynamic relation, which deal with physical processes and whether they occur spontaneously. The dimensions of entropy are energy divided by temperature, which is the same as the dimensions of Boltzmann's constant ($kB$) and heat capacity. The SI unit of entropy is $joule\ per\ kelvin$. [Wikipedia]
rdfs:isDefinedBy
rdfs:label
Thermodynamic Entropy(en)
View as:  CSV

Work in progress

RDF/XML 
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    xmlns:xsd="http://www.w3.org/2001/XMLSchema#" > 
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    <rdf:type rdf:resource="http://qudt.org/schema/qudt/QuantityKind"/>
    <j.1:description rdf:datatype="http://qudt.org/schema/qudt/LatexString">Thermodynamic Entropy is a measure of the unavailability of a system’s energy to do work. It is a measure of the randomness of molecules in a system and is central to the second law of thermodynamics and the fundamental thermodynamic relation, which deal with physical processes and whether they occur spontaneously. The dimensions of entropy are energy divided by temperature, which is the same as the dimensions of Boltzmann's constant ($kB$) and heat capacity. The SI unit of entropy is $joule\ per\ kelvin$. [Wikipedia]</j.1:description>
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    <rdfs:isDefinedBy rdf:resource="http://qudt.org/2.1/vocab/quantitykind"/>
    <rdfs:label xml:lang="en">Thermodynamic Entropy</rdfs:label>
    <j.2:broader rdf:resource="http://qudt.org/vocab/quantitykind/EnergyPerTemperature"/>
  </rdf:Description>
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TURTLE 
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<http://qudt.org/vocab/quantitykind/ThermodynamicEntropy>
  rdf:type <http://qudt.org/schema/qudt/QuantityKind> ;
  <http://purl.org/dc/terms/description> "Thermodynamic Entropy is a measure of the unavailability of a system’s energy to do work. It is a measure of the randomness of molecules in a system and is central to the second law of thermodynamics and the fundamental thermodynamic relation, which deal with physical processes and whether they occur spontaneously. The dimensions of entropy are energy divided by temperature, which is the same as the dimensions of Boltzmann's constant ($kB$) and heat capacity. The SI unit of entropy is $joule\\ per\\ kelvin$. [Wikipedia]"^^<http://qudt.org/schema/qudt/LatexString> ;
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  rdfs:isDefinedBy <http://qudt.org/2.1/vocab/quantitykind> ;
  rdfs:label "Thermodynamic Entropy"@en ;
  <http://www.w3.org/2004/02/skos/core#broader> <http://qudt.org/vocab/quantitykind/EnergyPerTemperature> ;
.
JSON 
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 ,"uri":"http:\/\/qudt.org\/vocab\/quantitykind\/ThermodynamicEntropy" 
 ,"properties":["applicable unit":"unit:KiloJ-PER-K" 
    ,"description":"Thermodynamic Entropy is a measure of the unavailability of a system\u2019s energy to do work. It is a measure of the randomness of molecules in a system and is central to the second law of thermodynamics and the fundamental thermodynamic relation, which deal with physical processes and whether they occur spontaneously. The dimensions of entropy are energy divided by temperature, which is the same as the dimensions of Boltzmann's constant ($kB$) and heat capacity. The SI unit of entropy is $joule\\ per\\ kelvin$. [Wikipedia]" 
    ,"has broader":"quantitykind:EnergyPerTemperature" 
    ,"has dimension vector":"dimension:A0E0L2I0M1H-1T-2D0" 
    ,"isDefinedBy":"&lt;http:\/\/qudt.org\/2.1\/vocab\/quantitykind&gt;" 
    ,"label":"Thermodynamic Entropy" 
    ,"normative reference (ISO)":"http:\/\/www.iso.org\/iso\/catalogue_detail?csnumber=31890" 
    ,"type":"qudt:QuantityKind" 
    ]}
JSON-LD 
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  "description" : "Thermodynamic Entropy is a measure of the unavailability of a system’s energy to do work. It is a measure of the randomness of molecules in a system and is central to the second law of thermodynamics and the fundamental thermodynamic relation, which deal with physical processes and whether they occur spontaneously. The dimensions of entropy are energy divided by temperature, which is the same as the dimensions of Boltzmann's constant ($kB$) and heat capacity. The SI unit of entropy is $joule\\ per\\ kelvin$. [Wikipedia]",
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    "@value" : "Thermodynamic Entropy"
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}
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