Document 6516691
Transcription
Document 6516691
1 What is ∆U? • A monatomic perfect gas at 0 oC is expanded from 22.4 dm3 to 44.8 dm3. 0 Paul Franklyn – School of Chemistry – Wits - 1 J 1 What is ∆U? • A monatomic perfect gas at 0 oC is expanded from 22.4 dm3 to 44.8 dm3. • ANSWER: – ∆U=0 internal energy is a function of T only Paul Franklyn – School of Chemistry – Wits - 2 2 What is ∆H? • A monatomic perfect gas at 0 oC is expanded from 22.4 dm3 to 44.8 dm3. 0 Paul Franklyn – School of Chemistry – Wits - 3 J 2 What is ∆H? • A monatomic perfect gas at 0 oC is expanded from 22.4 dm3 to 44.8 dm3. • ANSWER: – ∆H = 0J because it is isothermal Paul Franklyn – School of Chemistry – Wits - 4 3 Calculate w: • A monatomic perfect gas at 0 oC is expanded from 22.4 dm3 to 44.8 dm3 when this is done reversibly -15700 Paul Franklyn – School of Chemistry – Wits - 5 J 3 Calculate w: • A monatomic perfect gas at 0 oC is expanded from 22.4 dm3 to 44.8 dm3 when this is done reversibly • ANSWER: Vf dV w = −nRT ∫ = - nRT In[Vf/Vi] V Vi w = -1.57 kJ Paul Franklyn – School of Chemistry – Wits - 6 4 Calculate w: • A monatomic perfect gas at 0 oC is expanded from 22.4 dm3 to 44.8 dm3 when this is done under constant external pressure. -1130 Paul Franklyn – School of Chemistry – Wits - 7 J 4 Calculate w: • A monatomic perfect gas at 0 oC is expanded from 22.4 dm3 to 44.8 dm3 when this is done under constant external pressure. • ANSWER: • w = −p.∆V ∆V = (44.8 -22.4) dm3 = 22.4 dm3 pV = nRT so pext = pf = nRT/ Vf = (1.00 mol)(0.08206 dm3 atm K-1 mol-1)(273K) 44.8 dm = 0.500 atm = 5.065 x 104 Pa w = −p.∆V = −5.065 x 104 Pa x 22.4 dm3 = -1.13 kJ Paul Franklyn – School of Chemistry – Wits - 8 5 What is w? • A monatomic perfect gas at 0 oC is expanded from 22.4 dm3 to 44.8 dm3 when this is done freely. 0 Paul Franklyn – School of Chemistry – Wits - 9 J 5 What is w? • A monatomic perfect gas at 0 oC is expanded from 22.4 dm3 to 44.8 dm3 when this is done freely. • ANSWER: – No restoring pressure – So nothing to do work against Paul Franklyn – School of Chemistry – Wits - 10 6 Calculate ∆S for: • the following changes in state of 2.50 mol of a perfect monoatomic gas with CV.m = 1.5 R for all temperatures. • (1.50 atm, 400 K) → (3.00 atm, 600 K) 6.66 Paul Franklyn – School of Chemistry – Wits - 11 J/K 6 Calculate ∆S for: • the following changes in state of 2.50 mol of a perfect monoatomic gas with CV.m = 1.5 R for all temperatures. • (1.50 atm, 400 K) → (3.00 atm, 600 K) • ANSWER: – For an ideal gas with CV.m = 1.5 R at all T's, Eq (Eq 1 on page 26 of pink book) gives: ∆S = CV ln (T2/T1) + nR ln (V2/V1) = nR[1.5 ln(T2/T1) + ln(V2/V1)] = (2.50 mol)(8.314 J mol-1 K-1)(1.5 ln 1.5 + ln 0.75) = 6.66 J/K-1 Paul Franklyn – School of Chemistry – Wits - 12 7 How long (in seconds): to 3 sig figs? • Given the following second order reaction studied at 383oC: NO2(g) →NO(g) + O2(g) • Given that the rate constant for this reaction is 10 M-1s-1 and the experimental data on the right. • How long for the concentration of NO2(g) to drop down to 2.35% of what it originally was? Do not enter any units!!! 41.6 Paul Franklyn – School of Chemistry – Wits - 13 Time / [NO2(g)] / s M 0.0 0.100 5.0 0.017 10.0 15.0 0.0090 0.0062 20.0 0.0047 8 What is the activation energy? • Calculate the activation energy for a reaction whose rate constant at room temperature is doubled by an increase in temperature (T) by 10oC. 53 Paul Franklyn – School of Chemistry – Wits - 14 kJ/mol