1 / 51

Entropy

Entropy. Time’s Arrow. Objectives. Explain the tendency of matter and energy to spread out over time. Identify entropy changes in familiar processes. Poll Question. I heard of “entropy” before this course. True. False. Poll Question. I think I know what “entropy” means. True. False.

boyes
Download Presentation

Entropy

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Entropy Time’s Arrow

  2. Objectives • Explain the tendency of matter and energy to spread out over time. • Identify entropy changes in familiar processes.

  3. Poll Question I heard of “entropy” before this course. • True. • False.

  4. Poll Question I think I know what “entropy” means. • True. • False.

  5. The Flow of Matter particles disperse

  6. Gas Molecule in a Box No energy transfer to walls: elastic collisions

  7. Gas Molecule in a Box Double the size of the box!

  8. Gas Molecule in a Box Double the size of the box!

  9. a. Allb. Half c. noned. 75% Poll Question What portion of the time will the molecule spend in the original volume (left half of the box)?

  10. Poll Question What portion of the time will the molecule spend in the original space if we quadruple the volume of the box?

  11. a. Allb. Half c. 1/3d. 1/4 Poll Question What portion of the time will the molecule spend in the original space if we quadruple the volume of the box?

  12. a. 1b. 1/2 c. 1/3d. 1/4 Poll Question What is the probability that the molecule will be in the original space at any given time? V V/4

  13. a. 1b. 1/2 c. 1/4d. 0 Two Molecules (Poll) What is the probability that both will be in the left half of the container at the same time?

  14. a. 1/2b. 1/3 c. 1/4d. 1/8 Three Molecules (Poll) What is the probability that all three will be in the left half of the container at the same time?

  15. Whiteboard Work • What is the probability that all N will be in the given sector of the container at the same time? xV V

  16. Expansion Summary Random motions cause particles to spread out. The chance that they will randomly come back together decreases tremendously as the number of molecules increases. Spreading out is irreversible.

  17. Group It! Discuss all succeeding poll questions with your group before answering.

  18. The Flow of Energy energy disperses

  19. Collision! A moving object rams a stationary object. Before impact:Kinetic Energy of projectile > 0 Kinetic Energy of target = 0

  20. Group Poll Question What happens to the kinetic energy after the collision? • All of it goes to the target. • The projectile and target have equal kinetic energies. • The projectile keeps it all. • It depends; there isn’t enough information to know for sure.

  21. I did the math! I calculated the kinetic energies of object 1 (projectile) and object 2 (target) as a function of • Offset • Relative masses

  22. Energy Transfer: Mass Effect

  23. Energy Transfer: Mass Effect

  24. Energy Transfer: Offset Effect

  25. Energy Transfer: Offset Effect

  26. Energy Transfer: Offset Effect

  27. Collision Summary • Before impact, all the kinetic energy is in the motion of the projectile. • At impact, the kinetic energy almost always distributes to motion of both the projectile and target. • When two objects collide, their kinetic energies are usually closer after the collision than before. • Spreading out is irreversible.

  28. Kinetic Energy Randomizes • Spreads out over more objects • Spreads out in more directions • Work becomes internal energy

  29. Example • How does entropy increase when a ball is dropped, bounces, and eventually stops? • How is energy conserved? PEKErandom molecular KE

  30. Heat Transfer multiple interactions

  31. Heat Flow Two solids with different temperatures (average molecular kinetic energies) are brought into contact.

  32. Heat Flow Two solids with different temperatures (average molecular kinetic energies) are brought into contact. What happens to the atoms’ kinetic energies (temperatures)?

  33. Heat Flow Summary Molecular kinetic energy flows from high temperature objects to low temperature objects, but not the other way around. This is because kinetic energy tends to even out between colliding objects. There are more ways to distribute energy among many molecules than among few molecules.

  34. Heat Generation • Any energy molecular motion • Raises entropy • Energy less constrained • Effect more important at low temperatures • DS = q/T • Greater proportional increase in thermal energy at low T

  35. Temperature Difference Hot Cold heat Until Warm Warm Equilibrium

  36. Temperature Difference Hot Heat flows until total entropy stops increasing • Thermal equilibrium • Same temperature Cold heat DS DS high low DU DU

  37. Thermodynamic Temperature Hot 1/T = DS/DU DS = q/T Cold heat DS DS high low DU DU

  38. Overall Summary • Particles and energy tend to become spread out uniformly. • Entropy is a measure of how many different ways a state can be arranged. • libraryanalogy • Total entropy increases in all processes that actually occur.

  39. What It Means examples

  40. Interesting but vital point We cannot see most of the motion that occurs in our world.

  41. The Funnel and the Ice Pack • How can matter ever become localized? • Stars form • Rain falls • How can thermal motion ever decrease? • Refrigerators and heat pumps • First aid cold packs • Any time one thing becomes localized, something else spreads out more

  42. Entropy, Technically • W = number of “configurations” of a state • S = kB ln(W) = entropy of the state • DS = entropy change • DS = S2− S1 • = kBln(W2) − kBln(W1) • = kB ln(W2/W1)

  43. Free Expansion Example • W2/W1 = = xN N xV V • DS = kN ln(x) xV V

  44. Ice Melting Example • Solid  liquid • disperses matter DSc > 0 • constrains energy DST < 0 DSc DS DS 0 temp DST melting temperature

  45. Add Salt • Salt dissolves in liquid only • Raises S of liquid (+ salt) • Raises DSc lower melting temperature DSc DSc DS DS DS 0 temp DST original melting temperature

  46. Group Work Explain how your process increases entropy. Think about: • Could the reverse process occur? • What spreads out: matter, energy or both? How? • Why does total entropy increase?

  47. Overall • Pessimistic View • Energy degrades from more to less useful forms • Order becomes disorder • Rather: Increasing entropy is how we know something will happen!

  48. Chemical Thermodynamics • Enthalpy (DH) is heat transfer to surroundings • Spontaneous if DG = DH – TDS < 0 • Equivalent to DS – DH/T > 0 • DS is entropy change of system • DH/T is entropy change of surroundings • If a state changes spontaneously, entropy increases.

  49. Entropy and Evolution • Darwinian evolution is perfectly consistent with thermodynamics. • Energy from the sun powers life processes. • Energy from earth radiates into space. • Material order on earth can increase because energy is dispersed. • Entropy always increases!

  50. Sun, Earth, and Life • Tsun = 6000 K, Tearth = 300 K, Tspace = 3 K • DSsun = –Q/Tsun; DSearth = ±Q/Tearth • In a year, Q 8 GJ/m2of earth surface • DSsun = –1.3 MJ/K m2 • DSearth = 0 • DSsurr = +2.7 GJ/K m2 • 1000 kg/m2 “orderly” life diverts > 1.3 MJ/K • Plenty of entropy is created

More Related