Is Entropy at Its Lowest During the Big Bang Despite Being a Disorderly Event?

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Discussion Overview

The discussion revolves around the concept of entropy in relation to the Big Bang, questioning whether entropy was at its lowest during this event despite its characterization as disorderly. Participants explore the implications of entropy's increase over time, the nature of order and disorder, and the relationship between entropy and the structure of the universe.

Discussion Character

  • Debate/contested
  • Conceptual clarification
  • Exploratory

Main Points Raised

  • Some participants suggest that entropy increases with time, leading to the question of whether the Big Bang represents a point of lowest entropy.
  • Others argue that the Big Bang, while chaotic, may have had a form of order that contradicts the notion of low entropy.
  • A participant highlights the "thermodynamic arrow of time" as a reason for the impossibility of time travel and questions the coherence of the original inquiry.
  • There is a discussion on the vagueness of the term "order" and its relationship to entropy, with some asserting that a more precise definition is necessary.
  • One participant references the Boltzmann entropy theory to argue that the early universe was highly ordered by certain definitions of entropy.
  • Another participant points out that systems can appear more ordered while having higher entropy, using the example of a solar system formation.
  • Some participants note that the early universe was incredibly homogeneous, contrasting it with the current state of the universe.
  • There are philosophical considerations regarding the definitions of order and entropy, with some suggesting that these concepts may not align with intuitive understanding.
  • A later reply emphasizes the importance of avoiding simplistic analogies when discussing entropy and order.

Areas of Agreement / Disagreement

Participants express multiple competing views on the relationship between entropy, order, and the Big Bang. The discussion remains unresolved, with no consensus on whether the Big Bang represents a state of low entropy or not.

Contextual Notes

Limitations in definitions of order and entropy are noted, as well as the dependence on various interpretations of these concepts. The discussion also highlights the complexity of applying thermodynamic principles to cosmological events.

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the entropy level (disorder) increase with the time flow (as it the entropy is bigger in the future), so if we would go against the flow of time, time travel to the past then the entropy will decrease my question is if we will go back to the past till the big bang the moment of creation does that mean the entropy is at it's lowest there is relative order to the future now how can that be?
if I am not mistaken the creation of big bang is a thing of disorder isn't it?
 
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Are you speaking of the evolution of life or matter?

Nautica
 
The direction of increasing entropy is called the "thermodynamic arrow of time" and it is one of the main reasons you can't go back in time.

Now, your question itself is a fairly incoherent run-on sentence, so I'm not exactly sure what you are getting at. But since time and the universe start at the big bang (or rather, at a point in time just after the big bang), there is no "before" with which to measure a change in entropy before and after the big bang.

Overall, I guess you are asking if the big bang theory contradicts the second law of thermodynamics. No, it doesn't.
 
so it means order has been in the big bang.
to me it's contradictory because in the beginning there wasnt structure to the universe and now there is and as i understood it entropy is another word for disorder now how can it be that in the big bang there was more order than now?
 
'Order' is such a vague term, so when applying it to something quantifiable like entropy you have to be precise. Entropy is usually thought of as dS = dq/T, where dS is the change in entropy, dq is the energy absorbed by the system and T is the thermodynamic temperature, but in terms of the Boltzmann entropy theory it can be thought of as the following

S - S0 = k ln(W/W0) ----------------(1)

Where W is the number of microscopically distinct states that give rise to the same macroscopic state of the system (in terms of quantum mechanics this would be the number of solutions to the Schroedinger wave equation giving the same energy distribution), k is the Boltzmann constant, S0 is the entropy of a standard conditon and W0 is the probability of a standard condtion.

The third law of thermodynamics state that a perfect crystal at absolute zero has an entropy of zero using this fact and (1) you can then show that any non-perfect molecular configuration has a certain amount of what is known as configurational entropy that is intrinstic to it and this is what can be thought of as disorder. The early stages of the universe by this definition would be very ordered, infact incredibly so, IIRC the probability of the current universe sponateously revrting back to this amount of order would be 10-123.
 
Originally posted by Ambitwistor
As jcsd, "order" is a vague term. What one intuitively thinks of as "order" doesn't necessarily correspond to "low entropy".

For instance, take a cloud of gas, which gravitationally collapses to form a solar system, with a star, planets, etc. Would you say that the universe is more "ordered" after the formation of the solar system, than it was before? Maybe ... but does it have less entropy? No: it has more entropy. See:

http://groups.google.com/groups?selm=9thcur$6jd$2@woodrow.ucdavis.edu
http://groups.google.com/groups?selm=906b1c$81u$2@mark.ucdavis.edu
http://groups.google.com/groups?selm=aip9kj$bhk$2@woodrow.ucdavis.edu

(These articles are very similar to each other, but they have slightly different references and details, so I cited all three.)
that's what puzzled me too.
the universe has structure and although it is ordered it's entropy is high.
what is the term of "order" in physics? (i thought it was low entropy).
 
Read through the links that Ambitwistor posted, as they explain how in large systems where gravity pre-dominates, as entropy increases so does inhomogenity. The early universe was incredibly homogenous.
 
Originally posted by jcsd
Read through the links that Ambitwistor posted, as they explain how in large systems where gravity pre-dominates, as entropy increases so does inhomogenity. The early universe was incredibly homogenous.
also now the universe is homogenous.
if it wasnt then how could you say that the laws of physics apply everywhere in the universe?
 
Originally posted by Ambitwistor
As far as I know, there is no mathematical definition of "order" that corresponds in all cases to our intuition.
i think it's more a philosophical question then a mathematical one.
 
  • #10
Originally posted by loop quantum gravity
also now the universe is homogenous.
if it wasnt then how could you say that the laws of physics apply everywhere in the universe?

You are right the universe still is pretty homogenpus, but nowhere near as homogenous (and by homogenopus I mean homogenous in the distribution of it's matter) as it was in it's early stages.
 
  • #11
Originally posted by jcsd
You are right the universe still is pretty homogenpus, but nowhere near as homogenous (and by homogenopus I mean homogenous in the distribution of it's matter) as it was in it's early stages.
because the space where the universe just begun was... how should i put it, "small" and now as it's evolving so has matter evolved with space.
 
  • #12
And what has this evolution amounted to in terms of entropy? An increase.
 
  • #13
Originally posted by loop quantum gravity
i think it's more a philosophical question then a mathematical one.

Which brings us to the 4th law --- "It is impossible to do any useful thermodynamic work with a thesaurus." Entropy is a thermodynamic state function defined in the first half of the 19th century. This is prior to the statistical mechanical arguments. Statistical mechanics gives us partition functions for systems; if you must use the stat. mech. approach to analyzing questions involving entropy, WRITE THE PARTITION FUNCTION FOR THE SYSTEM! Don't appeal to the lame, intuitive (and incorrect) analogy that entropy is equivalent to a measure of disorder. And, NEVER take that lame analogy and run with it to the thesaurus --- order=structure=sequence=a thousand other untenable arguments (running with analogies is every bit as dangerous as running with scissors --- you WILL cut yourself).
 

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