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Course Webpage: http://panda.unm.edu/Courses/Thomas/Phys161fa10/P161Syllabus.htm Course Grading Policy You will want to get Mastering Physics and an iClicker Registration info on the webpage Key Points: Seven Midterms (Drop lowest score) No makeup exams Scantron but NOT multiple choice Model Exams Posted at least 2 weeks before midterm 0.1% of missed exam points for each problem done/ clicker quiz (up to a maximum of 50%)
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Chapter 17 Young&Freedman Some things are hot, some things are cold. Heating (usually) causes expansion. In thermal contact, two objects (eventually) reach the same temperature. Daniel Gabriel Fahrenheit (1686–1736) Fahrenheit temperature: The zero point was determined by placing the thermometer in brine: a mixture of ice, water, and ammonium chloride, a salt. This is a frigorific mixture. 96 degrees, was the level of the liquid in the thermometer when held in the mouth or under the armpit of his wife. Celsius used ice/water and water/steam for 0 and 100.
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Gases also expand on heating. Demo Kelvin temperature Units: K The ‘size’ of 1K = 1°C
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What is the approximate boiling temperature of water, in K? A] 100 K B] 212 K C] 273 K D] 373 K E] 485 K
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Solids also (usually) expand on heating.
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If I heat this metal annulus, The hole will: A] get smaller B] get bigger C] stay the same size
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Last time: Heat = Energy (that is transferred because of a difference in temperature). [The temperature difference may be VERY small!] “Specific Heat”, c, is the amount of heat needed to raise the temperature of a mass of material a degree (or a Kelvin) Q=mc “Latent heat” (of vaporization, or of fusion) is heat per mass of material needed to boil (vaporize) or freeze (fuse). Today: equilibration of water & ice mechanisms of heat transfer
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Mixing Ice & Water Mechanisms of heat transfer 1.Conduction 2.Convection (flow of fluid, like air) 3.Radiation
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Two square (in cross-section) glass rods connect very large copper blocks held at different temperatures. Which rod conducts heat faster? A] Rod A B] Rod B C] They conduct heat at the same rate
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Radiation. Hot objects emit light (glowing red hot, white hot, light bulb filaments, etc.) e = emissivity, e=1 is a ‘BLACK BODY’ Room temp: infrared emission Very hot: white emission VV hot: blue
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We can measure (approximately) the temperature of an object by looking at its black body spectrum. (This assumes that emissivity is independent of wavelength, which is often nearly true.)
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If an object can emit EM radiation (light, or infrared or UV etc.), then it must also absorb EM radiation. Consider an object in a vacuum box with perfectly reflective walls at temperature T. In thermal equilibrium, the object is emitting radiation: Since it does not change temperature, it must absorb the same amount of radiation. So e= emissivity = absorptivity! Black objects heat up faster in the sun, but cool off faster at night!
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The ideal gas law: A] Works with T (temp) in celsius or Kelvin, but you need to use a different R for each. B] Works with T in °C, °F, or K, but you need to use a different R for each. C] Works with T in °C or K, but if you use °C you need to use the “gauge pressure”, not absolute pressure D] Works only and exclusively with T in Kelvin.
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An ideal gas at 200 K occupies 2 liters at a pressure of 1 atm. If the gas is compressed to 1 liter of volume, what will be its temperature? A] 200 K B] 400 K C] 800 K D] There is not enough information to determine this!
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An ideal gas at 200 K occupies 2 liters at a pressure of 1 atm. If the gas is compressed to 1 liter of volume, and the pressure is 2 atm, what will be its temperature? A] 200 K B] 400 K C] 800 K D] There is not enough information to determine this!
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20 liters of Argon are in thermal equilibrium with 20 liters of Helium. (These are monatomic gases, M ar =40, M he =4.) Which molecules have more kinetic energy, on average? A] Argon B] Helium C] Both have the same Which molecules are moving faster, on average? HELIUM
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MON Aug 30
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W= Work Done BY a Gas = Memorize!
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When gas does work, it loses internal energy (unless energy is added, via heat.) When it does negative work, it gains internal energy
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A gas in a piston is taken from state 1 to state 2. The outside pressure is higher than the pressure in the cylinder. For which path does the gas do the largest positive work? A For which path does the gas do the most negative work? (I.e. for which path is the most work done ON the gas) Or choose E] no path does work of this sign
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In the isobaric process shown, W is: + A] + B] - C] 0 D] cannot determine In the isobaric process shown, U is: + In the isobaric process shown, Q is: +
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In the isochoric process shown, W is: 0 A] + B] - C] 0 D] cannot determine In the isochoric process shown, U is: - In the isochoric process shown, Q is: -
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In the isothermal process shown, W is: + A] + B] - C] 0 D] cannot determine In the isothermal process shown, U is: 0 In the isothermal process shown, Q is: + Let’s do this quantitatively. Wed Sept 1
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On expanding isothermally from 2L to 4L, an ideal gas does 6J of work, as the pressure drops from 2 atm to 1 atm. By how much must it expand to do an additional 6J of work? A] It must expand an additional 2L, to reach 6L B] It must double again, to 8L C] It must increase four-fold, to 16L D] It can do no more work, as it has reached 1 atm. E] Cannot determine without knowing T
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In the mystery path process shown, W is: D A] larger than for an isothermal process from A->B B] smaller than for an isothermal process from A->B C] 0 D] cannot determine In the mystery path process shown, U is: 0 In the mystery path process shown, Q is: D
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How much work is done when an ideal gas is expanded from V 1 to V 2 at constant pressure? A] 0 B] nRT 2 C] nRT 1 D] nR(T 2 -T 1 ) E] it depends on whether is it monatomic or diatomic. What is the difference in internal energy of the gas at points 1’ and 2 ? A
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For the cyclic process shown, W is: D A] 0, because it’s a loop B] p 0 V 0 C] - p 0 V 0 D] 2 p 0 V 0 E] 6 p 0 V 0 For the cyclic process shown, U is: A For the cyclic process shown, Q is: D For ONE cycle:
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Fri sept 3 For the constant pressure ideal gas process shown, The change in internal energy U of the gas is A] nC v B] nC p C] 0 D] cannot determine
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If the gas is monatomic and ideal, for the constant pressure process shown, the change in internal energy can also be expressed as: A] p V B] C] D] (use a paper & pencil)
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A non-ideal gas is taken from A to B. The gas does 3 J of work; 6 J of heat is added to the gas. What is the internal energy of the gas at B? A] 3 J B] 9 J C] 10 J D] cannot determine, since gas is non-ideal E] the numbers given are not physically possible
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A non-monatomic ideal gas is taken from A to B. The gas does 3 J of work; 6 J of heat is added to the gas. What is the internal energy of the gas at B? A] 3 J B] 9 J C] 10 J D] cannot determine, since gas is non-monatomic E] the numbers given are not physically possible
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