Chapter 10 Liquids & Solids



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1 Chapter 10 Liquids & Solids * 10.1 Polar Covalent Bonds & Dipole Moments - van der Waals constant for water (a = 5.28 L 2 atm/mol 2 ) vs O 2 (a = 1.36 L 2 atm/mol 2 ) -- water is polar (draw diagram) and O 2 is non-polar --- remind them about polarity and EN -- interaction between water molecules are electrostatic - polar bonds and polar molecules -- bond dipole --- change in EN between 2 atoms makes the bond connecting them polar --- this phenomenon leads to a bond dipole (arrow head points to the more EN atom) -- permanent dipole moment --- a molecule has a permanent dipole moment when it possesses an asymmetric orientation of polar bonds --- µ = Qr where Q is the partial electrical charge and r is the distance btwn the two atoms --- molecules that possess a permanent dipole: NH 3, H 2 O, SO 2, SF 4, XeOF 4 --- molecules that do not possess a permanent dipole: CBr 4, BF 3, BeCl 2, PCl 5, I - 3, SF 6, XeF 4

2 CH 3 Cl CH 2 Cl 2 CHCl 3 DPM = 1.87 debye DPM = 1.54 debye DPM = 1.02 debye CCl 4 DPM = 0.0 debye * 10.2 Intermolecular Forces - dipole-dipole interactions Figure 10.2 from the text -- we have attraction btwn the negative and positive poles shown in (a) -- we also have repulsion btwn the poles which are charged the same --- (+) (+) -- (-) (-) -- these dipoles happen because electron density is pulled from the less electronegative atoms toward the more electronegative ones -- recall the Electronegativity trend Figure from Chemistry by McMurray & Fey p. 59

3 --- the cationlike an atom the less EN and the reverse is also true - hydrogen bonds - dipole-dipole interaction that occurs btwn molecules possessing hydrogen and either O, N, or F. Figure 10.3 from text -- bond created by the close proximity of the lone pairs from the very EN atoms -- very strong dipole-dipole interaction -- contribute to the high boiling point of water -- lead to the double helical formation of DNA -- they also attribute to other properties that will be discussed later - ion- dipole: interactions btwn a cation/anion with a dipole Figure 9.5 from Chemistry: The Science in Context -- In this figure A. the O-atom in water is interacting with the positive cation (orange sphere) B. the H-atoms in water are interacting with the negative anion (yellow sphere) -- attractive forces btwn opposite charges -- very strong interaction leads to the larger value of the van der Waals a constant -- the more polar a molecule is the stronger the dipole-dipole interaction

4 Why do van der Waals constants have nonzero values for nonpolar species? - recall a = 1.36 L 2 atm/mol 2 for O 2 - polarization or polarizability: refers to the distortion of the electron cloud around the atom's nucleus as another atom or molecule approaches Figure 9.6 from Chemistry: The Science in Context -- this distortion occurs as a result of electron-electron repulsion btwn the atom and the approaching species -- the larger a molecule is the less tightly the electrons are held to the nucleus --- this makes it easier to distort the electron cloud --- therefore larger molecules are more polarizable -- comparison btwn He (a = 0.0341 L 2 atm/mol 2 ) versus Ar (a = 3.59 L 2 atm/mol 2 ) - London or dispersion forces: interactions btwn induced dipoles -- when an atom is polarized in the presence of another species this induced dipole occurs -- this is the type of interaction which happens btwn two non-polar species - e.g. N 2 molecules * 10.3 Some Properties of Liquids - surface tension: energy needed to separate the molecules of unit area on the surface of a liquid http://web.mit.edu/nnf/education/wettability/definition.html -- the reason a cold needle floats on the surface of water is because it is not dense enough to break the hydrogen bonds btwn the individual water molecules -- a hot needle will sink because the added temperature is enough to break the H- bonds - meniscus: curved surface of a liquid as a result of cohesive (H-bonds - e.g. water with water) or adhesive (dipole-dipole - e.g. water with glass) forces btwn solvent

5 and container molecules - capillary action: rise of a liquid up a narrow tube http://www.wtamu.edu/~crobinson/soilwater/capillar.html http://encyclopedia.farlex.com/_/viewer.aspx?path=hut&name=meni0001.jpg -- result of cohesive and adhesive forces --- cohesive forces occur btwn liquid molecules --- adhesive forces occur btwn liquid and solid molecules -- the way in which water flows upwards into trees and plants from the soil - viscosity: resistance of a fluid to flow -- molasses is very viscous -- water is not -- heating a fluid causes the viscosity to lower * 10.4 & 10.5 Phase Changes, Evaporation, Vapor Pressure, & Boiling Point Vapor pressure - vapor pressure is a result of molecules escaping from the liquid phase as gas - vaporization/evaporation is an endothermic process because energy/heat must be added to the system for a molecule to escape the liquid phase - heat of vaporization, H vap is the energy required to vaporize 1 mole of liquid at a pressure of 1 atm -- one of the ways we can measure the H vap is by generating a plot of ln(p vap ) versus 1/T -- this leads to a linear relationship as shown below: H vap 1 ln Pvap = + C R T b y m x - if we are measuring the vapor pressure over two temperatures then P vap, T H 1 1 1 vap ln = P vap, T R T 2 2 T1 - condensation is the opposite process in which gas molecules are cooled and become liquid this would therefore be an example of an exothermic process Other Changes of State - aside from going back and forth from liquid to gas we also have solid state Transitions - sublimation is another endothermic process in which solid goes to gas - solidification is the opposite effect in which liquid/gas is solidified - a solid may melt to form a liquid - for each one of these processes we have accompanying enthalpies e.g. H sub

6 - one final note: when a change of state is performed the intermolecular forces which led to the initial state must be overcome (e.g. to boil something the intermolecular forces in the liquid must be overwhelmed with our heat to the point molecules escape from the liquid to the gas phase) * 10.6 Kinds of Solids - crystalline vs. amorphous solids -- crystalline solid: cubic array of tightly packed atoms or molecules --- ionic solids NaCl http://metafysica.nl/nacl.jpg --- atomic solids buckminsterfullerene, C 60 http://www.ill.fr/dif/3d-crystals/ --- molecular solids ice http://chemed.chem.purdue.edu/genchem/topicreview/bp/ch14/graphics/14_12fig.gif -- amorphous solid: disordered structure e.g. volcanic glass * Structure & Bonding in Metals - lattice: refers to the 3D array of particles in a crystalline solid

7 -- lattice points: are the points of array that are occupied by a particle - unit cell: basic repeating unit of the particle arrangement in a crystalline solid - types of arrangements: -- simple cubic: has lattice points only at the eight corners of a unit cell -- body centered cubic: has eight corner lattice points as well as a center particle -- face-centered cubic: has 8 corner lattice points and a particle at the center of each of the six faces * 10.7 10.10 Skip * 21.4 21. 5 Bonding in Metals & Semiconductors Molecular Orbital Theory for Metals - recall MO diagrams draw one - the combo of two AOs leads to the generation of two MOs (these numbers are always equal) - Figure 21.7

8 -- as we increase the number of Na atoms we increase the number of AOs and hence the number of MOs generated -- eventually two bands will be formed --- lower band is comprised of bonding MOs and is referred to as the valence band --- the upper band is comprised of antibonding MOs and is referred to as the conduction band Semiconductors - Figure 21.10 -- typically all metals are conductors -- all nonmetals are insulators -- metalloids are semiconductors - when T is increased the conductivity of a semiconductor increases the opposite effect occurs for metals (structure begins to break melting begins) - We can increase the conductivity of semiconductors by adding impurities called dopants because we increase the number of charge carriers -- n-type semiconductor ( n = negative) --- adding a dopants with more electrons (adding P to a silicon network) --- the leftover electron is the charge carrier -- p-type semiconductor ( p = positive) --- adding a dopants with less electrons (adding B to a silicon network) --- the leftover hole is the charge carrier * 10.11 Phase Diagrams - the strength of intermolecular forces, temperature and pressure contribute to the phase (g, l, or s) of a molecule - at lower temperature and pressure gases are preferred whereas solids are more likely at higher temperatures and pressures - phase diagrams: graphical representation of the physical states as a function of T&P

9 http://encarta.msn.com/media_461541579/phase_diagram_for_water.html -- lines in the diagram: 1) melting point line: the state corresponding to this line is both solid and liquid 2) boiling point line: both gas and liquid present 3) sublimation point line: gas and solid present -- note for water this line has a negative slope - due to H-bonds -- usually this is positively sloped http://en.wikipedia.org/wiki/image:carbon_dioxide_pressuretemperature_phase_diagram.jpg -- the sublimation from ice to gas is what causes ice cubes to get smaller in the freezer -- triple point: point at which all three phases are present -- critical point: point at which liquid and gaseous state is indistinguishable --- the liquid phase is less dense due to high temperature --- the gas phase is more dense due to high pressure --- densities of the two states are the same -- normal points occur at 1 atm of pressure --- normal bpt for water is 100 C --- normal fpt for water is 0 C -- above this critical temperature and pressure we get a supercritical fluid --- has the physical properties of gas --- has the ability to dissolve substances like a liquid --- e.g. supercritical CO 2 to create decaffeinated coffee

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