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CHAPTER 5: Gases •Chemistry of Gases •Pressure and Boyle’s Law •Temperature and Charles’ Law •The Ideal Gas Law •Chemical Calculations of Gases •Mixtures of Gases •Kinetic Theory of Gases •Real Gases CHEM 1310 A/B Fall 2006 Gases • The states of matter: – Gas: fluid, occupies all available volume – Liquid: fluid, fixed volume – Solid: fixed volume, fixed shape – Others? … • Gases are the easiest to understand – can model them more precisely than liquids or solids using simple equations CHEM 1310 A/B Fall 2006 Ways to produce gases include… • Decomposition 2 HgO (s) → 2 Hg (l) + O2 (g) CaCO3 (s) + heat → CaO (s) + CO2 (g) etc. • Acids reacting with carbonates or hydrogen carbonates to release CO2 (chapter 4) NaHCO3 (s) + HCl (aq) → NaCl (aq) + H2O (l) + CO2 (g) • Acids react with metal Zn (s) + 2 HCl (aq) → ZnCl2 (aq) + H2 (g) CHEM 1310 A/B Fall 2006 Some properties of gases • Pressure (P) : how much force it exerts per unit area • Temperature (T) : how hot or cold (kinetic energy of gas molecules) • Volume (V) : space it takes up (the whole volume of the container it’s in) CHEM 1310 A/B Fall 2006 Pressure • Often measured by a barometer • The height of a column of mercury is related to the air pressure…Standard atmospheric pressure gives a column of mercury 76 cm high • How does this work? CHEM 1310 A/B Fall 2006 Pressure by barometer • Atmosphere pushes down on mercury in beaker, causes it to rise in column • Push of atmosphere exactly balanced by force due to weight of mercury (F=ma) • Mass of mercury is m = d A h, and a=g, so F = ma = dAhg • P = F/A = dgh CHEM 1310 A/B Fall 2006 Units of pressure • P = F / A = N / m2 = kg m s-2 / m2 = kg / ms2. SI unit “pascal” (Pa). 105 Pa = 1 bar. • Atmospheric pressure is 76 cm of Hg (or 760 mm Hg). Density is 13.596 g cm-1 (at 0o C) or 1.3596 x 104 kg m-3 • P = gdh = 9.80665 m/s2 x 1.3596 x 104 kg/m3 x 0.7600 m = 1.0133 x 105 kg / ms2 = 1.01325 x 105 Pa = “1 atmosphere” = 1 atm CHEM 1310 A/B Fall 2006 Connection between P & V: Boyle’s Law • • • • • Pressure and volume of a gas are related Use a “J tube” to figure out how In (a), pressure of atm exactly balances pressure of trapped gas Pgas = Patm In (b), pressure of gas is pressure balanced by Patm + that due to extra mercury added (=gdh), Pgas = Patm + gdh Gas is compressed (takes less V) and at higher pressure if more Hg is added CHEM 1310 A/B Fall 2006 Boyle’s Law • Boyle did experiments to show that if the pressure doubled, the gas took up ½ as much room, etc. Pressure and volume are inversely related P1 V1 = P2 V2 (for fixed T and amt of gas) or more generally, PV = C (constant at fixed T and amount of gas), where C is independent of the particular gas chosen! • C = 22.4 L atm at 0o C and 1 mol of gas; 0o C, 1atm are “standard temperature and pressure” (STP). At STP, one mol of gas occupies 22.4L CHEM 1310 A/B Fall 2006 Relationship between V&T: Charles’ Law • As T goes up (at constant pressure Patm), gas expands V = V0 + α V0 Tcel, Tcel in Celcius • All gases expand by the same relative amount when heated! (i.e., α is nearly the same for all gases!) • Celcius temperature scale: water freezes at 0oC, water boils at 100oC by definition! Easy. • On Celcius scale, α = 1/(273.15oC)… has a weird result when T=-273.15oC… “Absolute zero”. Can’t get below 273.15oC. • “Absolute temperature scale” T (Kelvin) = 273.15 + Tcel (Celcius) CHEM 1310 A/B Fall 2006 Relationship between V and T CHEM 1310 A/B Fall 2006 Charles’ Law in Kelvin T scale • If we substitute Tcel = T (Kelvin) – 273.15, we get V = a T, where a = V0 / 273.15 • So now (V1/V2) = (T1/T2) (for a fixed pressure and amount of gas) • Lots of easy problems can be worked with this… for example, if T (in Kelvin!) is doubled, what happens to V? CHEM 1310 A/B Fall 2006 Ideal Gas Law • Combines Charles’ Law and Boyle’s Law V α nT / P Volume is proportional to amount of gas and temperature, and inversely proportional to pressure. Call the constant of proportionality R (“universal gas constant”) PV = nRT R = 0.082058 L atm mol-1 K-1 = 8.3145 J mol-1 K-1 • Can do lots of easy problems relating P, V, n, T of a gas using this simple equation CHEM 1310 A/B Fall 2006 Example problem • A gas cylinder weighs 1.5 kg empty and 2.0 kg when filled with CO2 gas. If the cylinder has a volume of 1.0 L, what’s the pressure of the gas at 25oC? CHEM 1310 A/B Fall 2006 Ideal gas law w/ molar mass • Could have done the last problem more directly by re-casting the ideal gas law • N = m (mass) / M (molar mass) • PV = (m/M) RT • Also, since density d=m/V, d= PM/RT • Can predict density from P, T, M • Can determine M (and not just empirical formula!) from d, P, T CHEM 1310 A/B Fall 2006 Gases in chemical reactions • Can use ideal gas law to do stoichiometry problems now using P, T, V… instead of just masses • Example: We want to make 15.0 kg of the rocket fuel hydrazine, using the reaction 2 NH3 (g) + NaOCl (aq) → N2H4 (aq) + NaCl (aq) + H2O (l) • If our ammonia is at 10oC and 3.63 atm, how much of it (in L) do we need? CHEM 1310 A/B Fall 2006 Mixtures of gases • Suppose 3 containers of equal volume V, each of which contained 1 mol of gas at 1 atm of pressure H2 V, T, 1atm, 1mol O2 V, T, 1atm, 1mol N2 V, T, 1atm, 1mol • What happens if we take the O2 and N2 from the 2nd and 3rd containers and put them in the 1st container at constant T (and of course constant V)? What’s the total pressure? CHEM 1310 A/B Fall 2006 Mixtures of gases, cont’d H2, O2 N2 V, T 1 mol H2, 1 mol O2, 1 mol N2 • Partial pressure: pressure exerted by each gas in a gas mixture • Total pressure = sum of partial pressures • Each gas obeys ideal gas law separately for the number of moles of that gas and the partial pressure • Ideal gas law also holds for Ptot, ntot • PH2 = nH2 R T / V, etc. • Ptot = ntot R T / V • Therefore, PH2 / Ptot = nH2 / ntot ( = 1/3 for this example). This is also called the “mole fraction”, XH2 • PH2 = Ptot x XH2 ( = 1/3 Ptot for this example) CHEM 1310 A/B Fall 2006 Kinetic Theory of Gases • Tries to explain gas behavior using basic physics • Molecules of a gas fly around in random directions with a distribution of speeds • The molecules are pictured as hard objects undergoing elastic collisions with each other and the walls of the container • Pressure results from the many collisions of the gas molecules with the walls of the container. P = F/A, P α (impulse per collision) x (rate of collisions with walls) CHEM 1310 A/B Fall 2006 Origin of pressure • P = F/A P α (impulse per collision) x (rate of collisions with walls) P α (m x u) x [(N/V) x u] = Nmu2 / V, where u = speed of molecules m = mass of molecules (N/V) = number of molecules per unit volume (more molecules = more collisions) note faster molecules (u) = more collisions CHEM 1310 A/B Fall 2006 Origin of pressure, cont’d • So far we have PV α Nmu2 • Problem: not just one speed u, lots of them • Solution: ok to use an average over u2, the mean square speed <u2> • Proportionality constant works out to be 1/3, so PV = (1/3) Nm<u2>. But we also know PV = nRT, so nRT = (1/3) Nm<u2>, or RT = (1/3) N0 m<u2> (because N is just n times N0, Avogadro’s number) CHEM 1310 A/B Fall 2006 Origin of pressure, cont’d • So we see that RT = (1/3) N0 m<u2> • Temperature is therefore due to the kinetic energy of the gas molecules • KE = ½ m u2 • Average KE per mol is ½ (N0m) <u2> = 3/2 RT, or <u2> = 3RT / M (since molar mass M = N0m) • So… molecules move faster at higher T, and slower if they are more massive! CHEM 1310 A/B Fall 2006 Maxwell-Boltzmann distribution of molecular speeds in N2 at 3 temps Note: urms ≠ ump ≠ uav CHEM 1310 A/B Fall 2006 Measurement of speed distributions CHEM 1310 A/B Fall 2006 Root mean square (RMS) speed • Urms = sqrt(<u2>) = sqrt(3RT/M) • Example: He at 298K has what RMS speed? CHEM 1310 A/B Fall 2006 Diffusion • • • Result of previous example seems to large… e.g., odors don’t seem to travel this fast! Reason: direction of molecule keeps changing due to collisions with other gas molecules Diffusion: random motion of a molecule due to collisions with other molecules. Typically about 1010 collisions per second! Typically goes about ~ 10-7 m between collisions (mean free path) CHEM 1310 A/B Fall 2006 Rates of effusion and gaseous diffusion • Effusion: molecules escape through a very small hole into vacuum • Gaseous diffusion: molecules pass through a (large) porous barrier into another container • The rates of both of both processes are inversely proportional to the molar mass of the gas • Gaseous diffusion used to separate 235U from 238U in World War II CHEM 1310 A/B Fall 2006 Real gases • PV=nRT is the ideal gas law • Gases are not “ideal”. Implicitly assumes – Gas molecules are ideal “point particles” with no size – No attraction between molecules • In reality, gas molecules do take up some volume, and there is some attraction between gas molecules which can cause clustering • First effect reduces volume available to gas, and second reduces pressure exerted by gas • Van der Waals equation of state (P + a n2/V2) (V - nb) = nRT is more accuate. a,b depend on gas, are tabulated. n2/V2 is # of pairs per volume, and nb is excluded volume CHEM 1310 A/B Fall 2006 Reliability of ideal gas law • Different molecules deviate differently • Works best at low pressures • Deviations at very large pressures can be a factor of 2 or more CHEM 1310 A/B Fall 2006