Welcome to Anagrammer Crossword Genius! Keep reading below to see if eotropically is an answer to any crossword puzzle or word game (Scrabble, Words With Friends etc). Scroll down to see all the info we have compiled on eotropically.
eotropically
Searching in Crosswords ...
The answer EOTROPICALLY has 0 possible clue(s) in existing crosswords.
Searching in Word Games ...
The word EOTROPICALLY is NOT valid in any word game. (Sorry, you cannot play EOTROPICALLY in Scrabble, Words With Friends etc)
There are 12 letters in EOTROPICALLY ( A1C3E1I1L1O1P3R1T1Y4 )
To search all scrabble anagrams of EOTROPICALLY, to go: EOTROPICALLY?
Rearrange the letters in EOTROPICALLY and see some winning combinations
Scrabble results that can be created with an extra letter added to EOTROPICALLY
10 letters out of EOTROPICALLY
9 letters out of EOTROPICALLY
8 letters out of EOTROPICALLY
7 letters out of EOTROPICALLY
6 letters out of EOTROPICALLY
5 letters out of EOTROPICALLY
4 letters out of EOTROPICALLY
3 letters out of EOTROPICALLY
2 letters out of EOTROPICALLY
Searching in Dictionaries ...
Definitions of eotropically in various dictionaries:
No definitions found
Word Research / Anagrams and more ...
Keep reading for additional results and analysis below.
Eotropically might refer to |
---|
In statistical mechanics, Entropy is an extensive property of a thermodynamic system. It is closely related to the number Ω of microscopic configurations (known as microstates) that are consistent with the macroscopic quantities that characterize the system (such as its volume, pressure and temperature). Under the assumption that each microstate is equally probable, the entropy * * * * S * * * {\displaystyle S} * is the natural logarithm of the number of microstates, multiplied by the Boltzmann constant kB. Formally,* * * * S * = * * k * * * B * * * * ln * * Ω * * (assuming equiprobable microstates) * * . * * * {\displaystyle S=k_{\mathrm {B} }\ln \Omega {\text{ (assuming equiprobable microstates)}}.} * Macroscopic systems typically have a very large number Ω of possible microscopic configurations. For example, the entropy of an ideal gas is proportional to the number of gas molecules N. Roughly twenty liters of gas at room temperature and atmospheric pressure has N ≈ 6×1023 (Avogadro's number). At equilibrium, each of the Ω ≈ eN configurations can be regarded as random and equally likely. * The second law of thermodynamics states that the entropy of an isolated system never decreases. Such systems spontaneously evolve towards thermodynamic equilibrium, the state with maximum entropy. Non-isolated systems may lose entropy, provided their environment's entropy increases by at least that amount so that the total entropy increases. Entropy is a function of the state of the system, so the change in entropy of a system is determined by its initial and final states. In the idealization that a process is reversible, the entropy does not change, while irreversible processes always increase the total entropy. * Because it is determined by the number of random microstates, entropy is related to the amount of additional information needed to specify the exact physical state of a system, given its macroscopic specification. For this reason, it is often said that entropy is an expression of the disorder, or randomness of a system, or of the lack of information about it. The concept of entropy plays a central role in information theory. * Boltzmann's constant, and therefore entropy, have dimensions of energy divided by temperature, which has a unit of joules per kelvin (J K−1) in the International System of Units (or kg m2 s−2 K−1 in terms of base units). The entropy of a substance is usually given as an intensive property—either entropy per unit mass (SI unit: J K−1 kg−1) or entropy per unit amount of substance (SI unit: J K−1 mol−1). |