"entransy" meaning in All languages combined

{
  "etymology_templates": [
    {
      "args": {
        "1": "en",
        "2": "energy",
        "3": "transfer",
        "4": "ability",
        "alt1": "en􂀿ergy􂁀",
        "alt2": "trans􂀿fer􂁀",
        "alt3": "􂀿abilit􂁀y"
      },
      "expansion": "Blend of en[ergy] + trans[fer] + [abilit]y",
      "name": "blend"
    }
  ],
  "etymology_text": "Blend of en[ergy] + trans[fer] + [abilit]y, introduced on 26 February 2007 by a research group at Tsinghua University led by Professor Guo as a basis for optimizing heat transfer processes (Guo, Zeng-Yuan; Zhu, Hong-Ye; Liang, Xin-Gang. Entransy—a physical quantity describing heat transfer ability International Journal of Heat and Mass Transfer, no. 50, pp. 2545–56, available online 26 February 2007). A descriptive concept of entransy, but without using the term ‘entransy’, was first proposed by Professor Guo's group in February 2003 as ‘heat transport potential capacity’.",
  "forms": [
    {
      "form": "entransies",
      "tags": [
        "plural"
      ]
    }
  ],
  "head_templates": [
    {
      "args": {
        "1": "~"
      },
      "expansion": "entransy (countable and uncountable, plural entransies)",
      "name": "en-noun"
    }
  ],
  "lang": "English",
  "lang_code": "en",
  "pos": "noun",
  "senses": [
    {
      "categories": [
        {
          "kind": "other",
          "name": "English blends",
          "parents": [],
          "source": "w"
        },
        {
          "kind": "other",
          "name": "English entries with incorrect language header",
          "parents": [
            "Entries with incorrect language header",
            "Entry maintenance"
          ],
          "source": "w"
        },
        {
          "kind": "other",
          "name": "Pages with 1 entry",
          "parents": [],
          "source": "w"
        },
        {
          "kind": "other",
          "name": "Pages with entries",
          "parents": [],
          "source": "w"
        },
        {
          "kind": "topical",
          "langcode": "en",
          "name": "Thermodynamics",
          "orig": "en:Thermodynamics",
          "parents": [
            "Physics",
            "Sciences",
            "All topics",
            "Fundamental"
          ],
          "source": "w"
        }
      ],
      "examples": [
        {
          "ref": "2007, Zeng-Yuan Guo, Hong-Ye Zhu, Xin-Gang Liang, “Entransy—a physical quantity describing heat transfer ability”, in International Journal of Heat and Mass Transfer, number 50, page 2545:",
          "text": "A new physical quantity, E#x5F;h#x3D;#x5C;frac#x7B;1#x7D;#x7B;2#x7D;Q#x5F;#x7B;vh#x7D;T [where Qᵥₕ = McᵥT is the heat stored in an object; M is the mass; cᵥ is the specific heat capacity at constant volume; T is the temperature], has been identified as a basis for optimizing heat transfer processes in terms of the analogy between heat and electrical conduction. This quantity, which will be referred to as entransy, corresponds to the electric energy stored in a capacitor.",
          "type": "quote"
        },
        {
          "ref": "2017, Milivoje Kostic, “Entransy concept and controversies: A critical perspective within elusive thermal landscape”, in International Journal of Heat and Mass Transfer, number 115, page 340:",
          "text": "The concept of ‘entransy’, a product of heat and temperature, originally called ‘heat transport potential capacity’, was introduced in 2003, as analogy to product of electrical charge and voltage, as well as other similar quantities. The concept has been extended to entransy property, as integral product of ‘stored heat’ and temperature, #x5C;frac#x7B;1#x7D;#x7B;2#x7D;Mc#x5F;vT² [where M is mass; cᵥ is specific heat capacity at constant volume; T is temperature], thus representing quantity and quality of stored heat, or thermal energy in isochoric processes without work interactions.",
          "type": "quote"
        }
      ],
      "glosses": [
        "Half the product of internal thermal energy and temperature. For a given temperature difference, maximization of the entransy dissipation results in the maximum heat flux and thus corresponds to the optimal heat conduction performance."
      ],
      "id": "en-entransy-en-noun-cLg3e8SL",
      "links": [
        [
          "thermodynamics",
          "thermodynamics"
        ],
        [
          "thermal energy",
          "thermal energy"
        ],
        [
          "temperature",
          "temperature"
        ]
      ],
      "raw_glosses": [
        "(thermodynamics) Half the product of internal thermal energy and temperature. For a given temperature difference, maximization of the entransy dissipation results in the maximum heat flux and thus corresponds to the optimal heat conduction performance."
      ],
      "tags": [
        "countable",
        "uncountable"
      ],
      "topics": [
        "natural-sciences",
        "physical-sciences",
        "physics",
        "thermodynamics"
      ]
    }
  ],
  "word": "entransy"
}

{
  "etymology_templates": [
    {
      "args": {
        "1": "en",
        "2": "energy",
        "3": "transfer",
        "4": "ability",
        "alt1": "en􂀿ergy􂁀",
        "alt2": "trans􂀿fer􂁀",
        "alt3": "􂀿abilit􂁀y"
      },
      "expansion": "Blend of en[ergy] + trans[fer] + [abilit]y",
      "name": "blend"
    }
  ],
  "etymology_text": "Blend of en[ergy] + trans[fer] + [abilit]y, introduced on 26 February 2007 by a research group at Tsinghua University led by Professor Guo as a basis for optimizing heat transfer processes (Guo, Zeng-Yuan; Zhu, Hong-Ye; Liang, Xin-Gang. Entransy—a physical quantity describing heat transfer ability International Journal of Heat and Mass Transfer, no. 50, pp. 2545–56, available online 26 February 2007). A descriptive concept of entransy, but without using the term ‘entransy’, was first proposed by Professor Guo's group in February 2003 as ‘heat transport potential capacity’.",
  "forms": [
    {
      "form": "entransies",
      "tags": [
        "plural"
      ]
    }
  ],
  "head_templates": [
    {
      "args": {
        "1": "~"
      },
      "expansion": "entransy (countable and uncountable, plural entransies)",
      "name": "en-noun"
    }
  ],
  "lang": "English",
  "lang_code": "en",
  "pos": "noun",
  "senses": [
    {
      "categories": [
        "English blends",
        "English countable nouns",
        "English entries with incorrect language header",
        "English lemmas",
        "English nouns",
        "English terms with quotations",
        "English uncountable nouns",
        "Pages with 1 entry",
        "Pages with entries",
        "en:Thermodynamics"
      ],
      "examples": [
        {
          "ref": "2007, Zeng-Yuan Guo, Hong-Ye Zhu, Xin-Gang Liang, “Entransy—a physical quantity describing heat transfer ability”, in International Journal of Heat and Mass Transfer, number 50, page 2545:",
          "text": "A new physical quantity, E#x5F;h#x3D;#x5C;frac#x7B;1#x7D;#x7B;2#x7D;Q#x5F;#x7B;vh#x7D;T [where Qᵥₕ = McᵥT is the heat stored in an object; M is the mass; cᵥ is the specific heat capacity at constant volume; T is the temperature], has been identified as a basis for optimizing heat transfer processes in terms of the analogy between heat and electrical conduction. This quantity, which will be referred to as entransy, corresponds to the electric energy stored in a capacitor.",
          "type": "quote"
        },
        {
          "ref": "2017, Milivoje Kostic, “Entransy concept and controversies: A critical perspective within elusive thermal landscape”, in International Journal of Heat and Mass Transfer, number 115, page 340:",
          "text": "The concept of ‘entransy’, a product of heat and temperature, originally called ‘heat transport potential capacity’, was introduced in 2003, as analogy to product of electrical charge and voltage, as well as other similar quantities. The concept has been extended to entransy property, as integral product of ‘stored heat’ and temperature, #x5C;frac#x7B;1#x7D;#x7B;2#x7D;Mc#x5F;vT² [where M is mass; cᵥ is specific heat capacity at constant volume; T is temperature], thus representing quantity and quality of stored heat, or thermal energy in isochoric processes without work interactions.",
          "type": "quote"
        }
      ],
      "glosses": [
        "Half the product of internal thermal energy and temperature. For a given temperature difference, maximization of the entransy dissipation results in the maximum heat flux and thus corresponds to the optimal heat conduction performance."
      ],
      "links": [
        [
          "thermodynamics",
          "thermodynamics"
        ],
        [
          "thermal energy",
          "thermal energy"
        ],
        [
          "temperature",
          "temperature"
        ]
      ],
      "raw_glosses": [
        "(thermodynamics) Half the product of internal thermal energy and temperature. For a given temperature difference, maximization of the entransy dissipation results in the maximum heat flux and thus corresponds to the optimal heat conduction performance."
      ],
      "tags": [
        "countable",
        "uncountable"
      ],
      "topics": [
        "natural-sciences",
        "physical-sciences",
        "physics",
        "thermodynamics"
      ]
    }
  ],
  "word": "entransy"
}