fermionic condensate is a superfluid just like a the bose-einstein codensate but this time it has the property of molecular gasses that enable the fluidity to increase its temperature
Plasma condensate is a state of matter that is formed when a plasma gas is cooled and condensed into a liquid state. It is a dense and stable form of plasma that can have unique properties and applications in various fields such as energy production and materials science.
A Bose-Einstein condensate does have volume, but the volume is very small. All the atoms in a Bose-Einstein condensate are superimposed on each other, so no matter how many you have, the volume is that of a single atom.
Rubidium in itself is not an example of a Bose-Einstein condensate. The Bose-Einstein condensate is the fifth state of matter. Bose-Einstein condensate is a state of matter that only exists near absolute zero (zero degrees Kelvin) temperatures. Currently Rubidium is one of the only materials that scientists have caused to become a Bose-Einstein condensate. So Rubidium isn't an example of a Bose-Einstein condensate, its just an element that has been able to change state and become a Bose-Einstein condensate. Another one is Neutron star wich is the dead remains of a star that has exploded as a supernova. It is like a giant, dense, heavy nucleus of mostly neurons.
The unit of liquid condensate is typically measured in barrels (bbl) or gallons (gal). These units are commonly used to quantify the volume of liquid condensate produced or processed in the oil and gas industry.
To calculate the conversion of steam to condensate, you can use the formula: Steam Converted to Condensate = Steam Inlet - Steam Outlet This formula subtracts the amount of steam leaving the system (Steam Outlet) from the amount of steam entering the system (Steam Inlet) to determine the amount of steam that has been converted to condensate.
Yes. Dew is a condensate.
Not liquid but a gas; lithium condensate is a strange state of matter - a very diluted gas at a temperature near zero absolute. The properties of this phase are explained by the Bose-Einstein theory.
Not liquid but a gas; lithium condensate is a strange state of matter - a very diluted gas at a temperature near zero absolute. The properties of this phase are explained by the Bose-Einstein theory.
A Bose-Einstein condensate is a state of matter that can be found at extremely low temperatures, close to absolute zero. It is created in laboratories using techniques such as laser cooling. Some unique properties of a Bose-Einstein condensate include all the particles occupying the same quantum state, behaving as a single entity, and exhibiting wave-like properties. This state of matter allows for the study of quantum phenomena on a macroscopic scale.
Bose-Einstein condensate was first experimentally observed by Carl Wieman and Eric Cornell in 1995 at the University of Colorado. They were able to cool a gas of rubidium atoms to a temperature close to absolute zero, resulting in the formation of a condensate with unique quantum mechanical properties.
Naphtha is a petroleum condensate, therefore it is a condensate, therefore they are both condensate.
At 90 barg pressure, the freezing point of gas condensate is typically lower than at atmospheric pressure. The exact freezing point can vary depending on the composition of the gas condensate. It is advisable to consult the specific properties of the gas condensate mixture to determine its freezing point accurately at 90 barg pressure.
The 3 common phases of matter are solid, liquid, and gas. 1 less common phase of matter is plasma. 1 rare phase is Bose-Einstein condensate. 1 rare phase similar to the Bose-Einstein condensate is Fermionic condensate.
Plasma condensate is a state of matter that is formed when a plasma gas is cooled and condensed into a liquid state. It is a dense and stable form of plasma that can have unique properties and applications in various fields such as energy production and materials science.
Gas condensate is typically not recommended to be used as a direct replacement for diesel fuel. While both are hydrocarbons, gas condensate has different properties and may not meet the same standards and specifications required for diesel engines. Using gas condensate in place of diesel could potentially damage the engine and affect its performance.
A Bose-Einstein condensate can be found in extremely cold conditions, close to absolute zero, typically in laboratories. This state of matter is characterized by all particles occupying the same quantum state, behaving as a single entity with unique properties such as superfluidity and coherence.
The gas condensate is acidic. The acidity in the gas corrodes, therefore, forming sulphurised condensate droplets. Heating desulphurised the gas condensate.