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Paperwork. Next Week: Mon: Guest Lecture – Finish Ch. 20 Tues: Lab3 Wed: Problem Solving Friday: Guest Lecture – Begin Ch. 21 Today Problems 18&19 (maybe20) ?’s. Problem Ch. 18. Extension of 18.66 At what pressures does an ideal gas no longer behave like an ideal gas?
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Paperwork • Next Week: • Mon: Guest Lecture – Finish Ch. 20 • Tues: Lab3 • Wed: Problem Solving • Friday: Guest Lecture – Begin Ch. 21 • Today • Problems 18&19 (maybe20) • ?’s
Problem Ch. 18 • Extension of 18.66 • At what pressures does an ideal gas no longer behave like an ideal gas? • Consider Neutral O2 molecules • Size of 1 molecule ~ 2x10-10m • T = 300K • Container is sphere with diameter 1 m • Chemically Inert • Discuss: What makes an ideal gas ideal? • Look at pressure range from high to low
High Pressure Side • Looking for breakdown of pV=nRT • pV = NkBT • So edge of where this applies • When pressure gets too high, what happens? • Volume of one molecule ~ (2x10-10m)3 • p = (NkBT)/V • kB = 1.38x10-23 J/K • p ~ 714MPa ~ 7,000 atm ~ << Jupiter • At 1K P ~ 23 atm (300psi) << welding tank • Low T physics is fun (Shand)
Low Pressure Side • Ideal gas – gas bounces off each other! • When gas bounces off container more than gas – completely different physics • Look at mean free path
Low Pressure Side • Ideal gas – gas bounces off each other! • When gas bounces off container more than gas – completely different physics • Look at mean free path • What defines l? • When M.F.P. ~ l things go funny! No longer “fluid” Implications?
Low Pressure Side • Consider Neutral O2 molecules • Size of 1 molecule ~ r=2x10-10m • T = 300K • Container is sphere with diameter 1 m • Chemically Inert p ~ 6 mPa ~ 6x10-8 atm ~ 4.5x10-5 Torr Good vacuum pump or cruddy outer space vacuum (near earth?) Notice what happens when you reduce container size (or particle #) If l = 1nm p = 60 atm (low side) so at room pressure gas non-ideal Why is nanoscience cool? Why are “semi” metals fun? Also interesting aspects of different dimensions Surface area of sphere 4pr2 (see in above eq.) “surface area” of circle (2D) is 2pr…
Chapter 19 • 19.36: A player bounces a basketball on the floor, compressing it to 80.0 % of its original volume. The air (assume it is essentially N2 gas) inside the ball is originally at a temperature of 20.0oC and a pressure of 2.00 atm. The ball's diameter is 23.9 cm. • A) What is T at max compression? • B) What is change in U (of air inside ball) from original state to maximum compression? • How to solve: First set up knowns & unknowns & tools we’ll need. • Tools = Equations/Conservation Laws/Constraints
Parameters: Gas StuffpV = nRTQ = DU + W • 19.36: A player bounces a basketball on the floor, compressing it to 80.0 % of its original volume. The air (assume it is essentially N2 gas) inside the ball is originally at a temperature of 20.0oC and a pressure of 2.00 atm. The ball's diameter is 23.9 cm. • First find T at max compression (part A, why not?) • Original • p0 = 2 atm ~ 203 kPa • T0 = 20oC ~ 293 K • V0 = (4/3)pr3 = 5.72x10-2 m3 • Universal • M = 28 g/mol [Always] • R = 8.31 • n = (p0V0)/(RT0) = 4.77 mol • Final • VF = 0.8 V0 = 4.57x10-2 m3 • Now what? • Type of process? • What is constant? • T? V? p? Q? W? n? m?
Parameters: Gas StuffpV = nRTQ = DU + W • 19.36: A player bounces a basketball on the floor, compressing it to 80.0 % of its original volume. The air (assume it is essentially N2 gas) inside the ball is originally at a temperature of 20.0oC and a pressure of 2.00 atm. The ball's diameter is 23.9 cm. • First find T at max compression (part A, why not?) • Original • p0 = 2 atm ~ 203 kPa • T0 = 20oC ~ 293 K • V0 = (4/3)pr3 = 7.15x10-3 m3 • Universal • M = 28 g/mol [Always] • R = 8.31 • n = (p0V0)/(RT0) = 4.77 mol • Final • VF = 0.8 V0 = 5.67x10-3 m3 • Q constant Adiabatic • T0(V0)g-1 = TF(VF)g-1 • g = 1.4 (diatomic) • TF = T0 (V0/VF)g-1 • TF = T0 (1/.8).4 = 320 K
Parameters: Gas StuffpV = nRTQ = DU + W • 19.36: A player bounces a basketball on the floor, compressing it to 80.0 % of its original volume. The air (assume it is essentially N2 gas) inside the ball is originally at a temperature of 20.0oC and a pressure of 2.00 atm. The ball's diameter is 23.9 cm. • First find DU. • Original • p0 = 2 atm ~ 203 kPa • T0 = 20oC ~ 293 K • V0 = (4/3)pr3 = 7.15x10-3 m3 • Universal • M = 28 g/mol [Always] • R = 8.31 • n = (p0V0)/(RT0) = 0.59 mol • Final • VF = 0.8 V0 = 5.67x10-3 m3 • Q constant Adiabatic • T0(V0)g-1 = TF(VF)g-1, g=1.4 • TF = 320 K • Ideal Gas: DU = CVnDT • Air: CV ~ 20 J/(mol K) • DU = 345 J (Why CV?)
Why is DU dependent on CV? • Know: DU depends ONLY on T • Examine constant V case • dQ = dU + dW • dW = 0 if dV = 0 • dQ = nCVdT (heat for constant volume) • dU = nCVdT DU = nCVDT • So what happens for adiabatic? • Same thing, if true for one, true for all • Depends ONLY ON T, not PATH
Friday Monday: Guest Lecture Finish Ch. 20