high-temperature viscosimeter - significado y definición. Qué es high-temperature viscosimeter
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Qué (quién) es high-temperature viscosimeter - definición

TYPE OF NUCLEAR REACTOR THAT OPERATES AT HIGH TEMPERATURES AS PART OF NORMAL OPERATION
Hard to Receive; Very-High-Temperature Reactor; VHTR; High temperature gas cooled reactor; High Temperature Gas Cooled Reactor; HTGR; Advanced High-Temperature Reactor; Very High Temperature Reactor; High temperature gas reactor; High temperature gas-cooled reactor; High-temperature gas-cooled reactor; Very high temperature reactor; High-temperature-gas-cooled-reactor; Very-high-temperature reactor

High-temperature superconductivity         
  • rare-earths]]. BSCCO is a [[cuprate superconductor]] based on [[bismuth]] and [[strontium]]. Thanks to its higher operating temperature, cuprates are now becoming competitors for more ordinary [[niobium]]-based superconductors, as well as [[magnesium diboride]] superconductors.
  • Crystal lattice of Cuprate of Bismuth and Strontium ([[BSCCO]])
  • df           = dmy-all
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  • Small magnet levitating above a high-temperature superconductor cooled by [[liquid nitrogen]]: this is a case of [[Meissner effect]].
  • [[Phase diagram]] for high-temperature superconductors based on iron.<ref name="Kordyuk2012"/>
  • Timeline of superconductor discoveries. On the right one can see the liquid nitrogen temperature, which usually divides superconductors at high from superconductors at low temperatures. [[Cuprate]]s are displayed as blue diamonds, and [[iron-based superconductor]]s as yellow squares. [[Magnesium diboride]] and other low-temperature or high-pressure metallic [[BCS superconductor]]s are displayed for reference as green circles.
MATERIALS THAT BEHAVE AS SUPERCONDUCTORS AT UNUSUALLY HIGH TEMPERATURES
High-temperature superconductors; High-temperature superconductor; High temperature superconductor; High temperature superconductivity; HTSC; High temperature superconductors; Fermi surface of superconducting cuprates; Fermi surface of HTSC; Fermi surface of CuO plane; Fermi surface of BSCCO; Fermiology of HTSC; High-Temperature Superconducting; High-temperature superconducter; High-temperature Superconductivity; HgBa2Ca2Cu3Ox; High-temperature superconducting; High Temperature Superconductivity; HTC superconductor
High-temperature superconductors (abbreviated high-c or HTS) are operatively defined as materials that behave as superconductors at temperatures above , the boiling point of liquid nitrogen, one of the simplest coolants in cryogenics.
Absolute Temperature         
  • '''Figure 2.5''' This simulation illustrates an argon atom as it would appear through a 400-power optical microscope featuring a reticle graduated with 50-micron (0.05&nbsp;mm) tick marks. This atom is moving with a velocity of 14.43 microns per second, which gives the atom a kinetic temperature of one-trillionth of a kelvin. The atom requires 13.9 seconds to travel 200 microns (0.2&nbsp;mm). Though the atom is being invisibly jostled due to zero-point energy, its translational motion seen here comprises all its kinetic energy.
  • '''Figure 7''' Water's temperature does not change during phase transitions as heat flows into or out of it. The total heat capacity of a mole of water in its liquid phase (the green line) is 7.5507&nbsp;kJ.
  • [[Joseph Louis Gay-Lussac]]
  • [[Guillaume Amontons]]
  • [[Johann Heinrich Lambert]]
  • [[Jacques Alexandre César Charles]]
  • [[Macquorn Rankine]]
ABSOLUTE MEASURE OF TEMPERATURE
Absolute temperature; Absolute Temperature; Thermodynamic temperature scale; Kelvin temperature; Temperature (thermodynamic); Atoms can have zero kinetic velocity and simultaneously be vibrating due to zero-point energy
Temperature reckoned from absolute zero (see "Zero, Absolute"). It is obtained by adding for the centigrade scale 273, and for the Fahrenheit scale 459, to the degree readings of the regular scale.
absolute temperature         
  • '''Figure 2.5''' This simulation illustrates an argon atom as it would appear through a 400-power optical microscope featuring a reticle graduated with 50-micron (0.05&nbsp;mm) tick marks. This atom is moving with a velocity of 14.43 microns per second, which gives the atom a kinetic temperature of one-trillionth of a kelvin. The atom requires 13.9 seconds to travel 200 microns (0.2&nbsp;mm). Though the atom is being invisibly jostled due to zero-point energy, its translational motion seen here comprises all its kinetic energy.
  • '''Figure 7''' Water's temperature does not change during phase transitions as heat flows into or out of it. The total heat capacity of a mole of water in its liquid phase (the green line) is 7.5507&nbsp;kJ.
  • [[Joseph Louis Gay-Lussac]]
  • [[Guillaume Amontons]]
  • [[Johann Heinrich Lambert]]
  • [[Jacques Alexandre César Charles]]
  • [[Macquorn Rankine]]
ABSOLUTE MEASURE OF TEMPERATURE
Absolute temperature; Absolute Temperature; Thermodynamic temperature scale; Kelvin temperature; Temperature (thermodynamic); Atoms can have zero kinetic velocity and simultaneously be vibrating due to zero-point energy
¦ noun a temperature measured from absolute zero in kelvins.

Wikipedia

High-temperature gas reactor

A high-temperature gas-cooled reactor (HTGR), is a nuclear reactor that uses a graphite moderator with a once-through uranium fuel cycle. The HTGR is a type of high-temperature reactor (HTR) that can conceptually have an outlet temperature of 750 °C (1,380 °F). The reactor core can be either a "prismatic block" (reminiscent of a conventional reactor core) or a "pebble-bed" core. The high temperatures enable applications such as process heat or hydrogen production via the thermochemical sulfur–iodine cycle.

The HTR is the predecessor of the Very-high-temperature reactor (VHTR), one of the future Generation IV reactor-models, which initially would work with temperatures of 750 to 950 °C.