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Premium member Presentation Transcript Slide 1: Chemistry SOL Reviewby Anne Mooring (Jamestown High School, Williamsburg VA, 2006) Part 5: Phases of Matter and Kinetic Molecular Theory Intermolecular Forces Kinetic Molecular Theory Molar Heats of Fusion and Vaporization Specific Heat Capacity Calculations Colligative Properties Use the SOL periodic table. Click here for link This section represents 8/50 of the SOL questions You will need a calculator and periodic table to complete this section. Slide 2: Chemistry SOL Review— Phases of Matter Intermolecular Forces COVALENT BOND POLARITY non-polar covalent bonds: bonding electrons shared equally between two atoms Example: H2 polar covalent bonds (polar bonds): bonding electrons shared unequally. Example: HCl BOND POLARITY BASED ON ATOMS’ ELECTRONEGATIVITY the more electronegative atom acquires a slight negative charge (δ-). the less electronegative atom acquires a slight positive charge(δ+ ). The unequal sharing creates “polarized” bonds with opposite charges. Two ways to show polarity in structural formulas. δ- and δ+ or a slashed arrow pointing toward electronegative element δ+ δ- Slide 3: Chemistry SOL Review— Phases of Matter Intermolecular Forces POLAR MOLECULES Polar Molecules: One end of the molecule is slightly negative, and one end is slightly positive. Symmetric molecules are usually nonpolar. The polarities all cancel out. The CO2 molecule is nonpolar. When the arrows do not cancel the molecule is polar as in water. Unsymmetrical molecules are polar if there are polar bonds in the structure. Slide 4: Chemistry SOL Review— Phases of Matter Intermolecular Forces Intermolecular Attractions are attractions between molecules due to three forces Dispersion forces (weakest) are temporary attractions between molecules due to temporary dipoles due to shifting electron clouds. Dispersion forces are greater in larger molecules with larger electron “clouds”. Dipole interactions: polar molecules are attracted to each other. The positive dipole of one molecule is attracted to the negative dipole of another. Example: HCl molecules Slide 5: Chemistry SOL Review— Phases of Matter Intermolecular Forces Intermolecular Attractions are attractions between molecules due to three forces Hydrogen bond: hydrogen that is covalently bonded to a very electronegative atom is also weakly bonded to the unshared pair of another electronegative atom. Hydrogen bonding is the strongest intermolecular force. This explains water’s high boiling point. Slide 6: Chemistry SOL Review— Phases of Matter Intermolecular Forces Intermolecular Attractions and Molecular Properties As intermolecular forces increase, the molecules are held more strongly together. Solids resist melting because melting requires breaking intermolecular attractions and reforming new ones as the molecules slide past each other. Liquids resist boiling because the liquid molecules will have to overcome the intermolecular attraction of the other liquid molecules to enter the gas phase. Slide 7: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory Kinetic Molecular Theory: The tiny particles in all forms of matter are in constant motion. As kinetic energy increases, temperature increases. Kinetic Energy is directly proportional to the Kelvin temperature scale. At zero Kelvin, K, all molecular motion theoretically stops. 0°C = 273K Slide 8: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory GASES Gas pressure is measured in atmospheres, kilopascals (kPa), or mm Hg One atmosphere = 101.3 kPa = 760 mm Hg Assumptions relating to gases: Gas particles have negligible volume compared to container size Gas particles do not attract or repel each other* Gas particle move constantly, rapidly and randomly All collisions are perfectly elastic (particles collide like billiard balls, not marshmallows) However, gas particles really do attract each other due to intermolecular forces Slide 9: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory LIQUIDS When gas molecules lose kinetic energy (cool and slow down) then intermolecular forces can cause the molecules to stick together and liquify. Evaporation: molecules with enough kinetic energy to overcome the intermolecular attractions in a liquid can escape the liquid and enter the gas phase. Vapor Pressure: the force due to the gas above a liquid. This increases as temperature increases. The curves are different for each liquid due to intermolecular forces Slide 10: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory LIQUIDS Boiling Point: the temperature where a liquid’s vapor pressure equals the external pressure or atmospheric pressure. Boiling Point increases as external/atmospheric pressure increases. Boiling Point decreases as external/atmospheric pressure decreases. Slide 11: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory LIQUIDS Slide 12: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory SOLIDS Particles in liquids are free to slide past each other Particles in solids do not slide past each other, but vibrate in place. Melting point: temperature where a solid becomes a liquid. Slide 13: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory PHASE CHANGES OR CHANGES OF STATE Triple Point—combination of temperature and pressure where all three phases coexist Slide 14: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory PHASE CHANGES OR CHANGES OF STATE a to b: solid increases in temperature. b to c: solid melts to liquid at a constant temperature c to d: liquid increases in temperature d to e: liquid vaporizes to gas at a constant temperature e to f: gas increases in temperature Slide 15: Chemistry SOL Review— Phases of Matter Molar Heats of Fusion and Vaporization Molar heat of fusion: the energy required to melt one mole of a substance. (ΔHfusion) Molar heat of vaporization: the energy required to vaporize one mole of a substance. (ΔHvaporization) ΔHfusion ΔHvaporization Slide 16: Chemistry SOL Review— Phases of Matter Molar Heats of Fusion and Vaporization Calculations Example 1:How much energy is required to melt 10.0 grams of ice into water? The heat of fusion of ice is 80.0 calories/(gx°C). Example 2: How much energy is required to vaporize 36.02 grams of water to steam at 100°C? Water’s molar heat of vaporization is 6.01 kJ per mole. Slide 17: Chemistry SOL Review— Phases of Matter Specific Heat Capacity Calculations Specific Heat Capacity: The amount of energy needed to raise one gram of a substance by 1°C. Units = J/(gx°C) Memorize q = mCΔT Use q=mC ΔT here Slide 18: Chemistry SOL Review— Phases of Matter Specific Heat Capacity Calculations q = mCΔT q = heat in joules, J m = mass in grams C = specific heat capacity ΔT = Tfinal – Tinitial Example 1: A 15 gram sample of water is warmed from 45° to 65°C. The specific heat capacity of water is 4.18 J/(gx°C). How much energy was required to warm the water? Answer: q = (15)(4.18)(65-45) = (15)(4.18)(20) = 1254 Joules Example 2: A 2.0 gram sample of metal requires 5.0 Joules of energy to warm from 10 to 20°C. What is the metal’s specific heat capacity? Answer: 5.0=(2.0)(C)(20-10) or 5.0=(2.0)(C)(10) and C = 0.25 J/(gx°C). Slide 19: Chemistry SOL Review— Phases of Matter Colligative Properties Adding impurities to a liquid increases the boiling point and decreases the freezing point (widens the liquid temperature range) Examples: Adding antifreeze to the water in the radiator to prevent boiling in summer and freezing in winter. Putting salt on the road to prevent the road from icing up. Slide 20: Chemistry SOL Review--Molar Relationships References http://www.markrosengarten.com/ for New York Regent’s exam powerpoint. You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
SOL Review Part 5 Phases of Matter aSGuest5375 Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINT lite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 764 Category: Education License: All Rights Reserved Like it (0) Dislike it (0) Added: December 04, 2008 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Slide 1: Chemistry SOL Reviewby Anne Mooring (Jamestown High School, Williamsburg VA, 2006) Part 5: Phases of Matter and Kinetic Molecular Theory Intermolecular Forces Kinetic Molecular Theory Molar Heats of Fusion and Vaporization Specific Heat Capacity Calculations Colligative Properties Use the SOL periodic table. Click here for link This section represents 8/50 of the SOL questions You will need a calculator and periodic table to complete this section. Slide 2: Chemistry SOL Review— Phases of Matter Intermolecular Forces COVALENT BOND POLARITY non-polar covalent bonds: bonding electrons shared equally between two atoms Example: H2 polar covalent bonds (polar bonds): bonding electrons shared unequally. Example: HCl BOND POLARITY BASED ON ATOMS’ ELECTRONEGATIVITY the more electronegative atom acquires a slight negative charge (δ-). the less electronegative atom acquires a slight positive charge(δ+ ). The unequal sharing creates “polarized” bonds with opposite charges. Two ways to show polarity in structural formulas. δ- and δ+ or a slashed arrow pointing toward electronegative element δ+ δ- Slide 3: Chemistry SOL Review— Phases of Matter Intermolecular Forces POLAR MOLECULES Polar Molecules: One end of the molecule is slightly negative, and one end is slightly positive. Symmetric molecules are usually nonpolar. The polarities all cancel out. The CO2 molecule is nonpolar. When the arrows do not cancel the molecule is polar as in water. Unsymmetrical molecules are polar if there are polar bonds in the structure. Slide 4: Chemistry SOL Review— Phases of Matter Intermolecular Forces Intermolecular Attractions are attractions between molecules due to three forces Dispersion forces (weakest) are temporary attractions between molecules due to temporary dipoles due to shifting electron clouds. Dispersion forces are greater in larger molecules with larger electron “clouds”. Dipole interactions: polar molecules are attracted to each other. The positive dipole of one molecule is attracted to the negative dipole of another. Example: HCl molecules Slide 5: Chemistry SOL Review— Phases of Matter Intermolecular Forces Intermolecular Attractions are attractions between molecules due to three forces Hydrogen bond: hydrogen that is covalently bonded to a very electronegative atom is also weakly bonded to the unshared pair of another electronegative atom. Hydrogen bonding is the strongest intermolecular force. This explains water’s high boiling point. Slide 6: Chemistry SOL Review— Phases of Matter Intermolecular Forces Intermolecular Attractions and Molecular Properties As intermolecular forces increase, the molecules are held more strongly together. Solids resist melting because melting requires breaking intermolecular attractions and reforming new ones as the molecules slide past each other. Liquids resist boiling because the liquid molecules will have to overcome the intermolecular attraction of the other liquid molecules to enter the gas phase. Slide 7: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory Kinetic Molecular Theory: The tiny particles in all forms of matter are in constant motion. As kinetic energy increases, temperature increases. Kinetic Energy is directly proportional to the Kelvin temperature scale. At zero Kelvin, K, all molecular motion theoretically stops. 0°C = 273K Slide 8: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory GASES Gas pressure is measured in atmospheres, kilopascals (kPa), or mm Hg One atmosphere = 101.3 kPa = 760 mm Hg Assumptions relating to gases: Gas particles have negligible volume compared to container size Gas particles do not attract or repel each other* Gas particle move constantly, rapidly and randomly All collisions are perfectly elastic (particles collide like billiard balls, not marshmallows) However, gas particles really do attract each other due to intermolecular forces Slide 9: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory LIQUIDS When gas molecules lose kinetic energy (cool and slow down) then intermolecular forces can cause the molecules to stick together and liquify. Evaporation: molecules with enough kinetic energy to overcome the intermolecular attractions in a liquid can escape the liquid and enter the gas phase. Vapor Pressure: the force due to the gas above a liquid. This increases as temperature increases. The curves are different for each liquid due to intermolecular forces Slide 10: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory LIQUIDS Boiling Point: the temperature where a liquid’s vapor pressure equals the external pressure or atmospheric pressure. Boiling Point increases as external/atmospheric pressure increases. Boiling Point decreases as external/atmospheric pressure decreases. Slide 11: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory LIQUIDS Slide 12: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory SOLIDS Particles in liquids are free to slide past each other Particles in solids do not slide past each other, but vibrate in place. Melting point: temperature where a solid becomes a liquid. Slide 13: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory PHASE CHANGES OR CHANGES OF STATE Triple Point—combination of temperature and pressure where all three phases coexist Slide 14: Chemistry SOL Review— Phases of Matter Kinetic Molecular Theory PHASE CHANGES OR CHANGES OF STATE a to b: solid increases in temperature. b to c: solid melts to liquid at a constant temperature c to d: liquid increases in temperature d to e: liquid vaporizes to gas at a constant temperature e to f: gas increases in temperature Slide 15: Chemistry SOL Review— Phases of Matter Molar Heats of Fusion and Vaporization Molar heat of fusion: the energy required to melt one mole of a substance. (ΔHfusion) Molar heat of vaporization: the energy required to vaporize one mole of a substance. (ΔHvaporization) ΔHfusion ΔHvaporization Slide 16: Chemistry SOL Review— Phases of Matter Molar Heats of Fusion and Vaporization Calculations Example 1:How much energy is required to melt 10.0 grams of ice into water? The heat of fusion of ice is 80.0 calories/(gx°C). Example 2: How much energy is required to vaporize 36.02 grams of water to steam at 100°C? Water’s molar heat of vaporization is 6.01 kJ per mole. Slide 17: Chemistry SOL Review— Phases of Matter Specific Heat Capacity Calculations Specific Heat Capacity: The amount of energy needed to raise one gram of a substance by 1°C. Units = J/(gx°C) Memorize q = mCΔT Use q=mC ΔT here Slide 18: Chemistry SOL Review— Phases of Matter Specific Heat Capacity Calculations q = mCΔT q = heat in joules, J m = mass in grams C = specific heat capacity ΔT = Tfinal – Tinitial Example 1: A 15 gram sample of water is warmed from 45° to 65°C. The specific heat capacity of water is 4.18 J/(gx°C). How much energy was required to warm the water? Answer: q = (15)(4.18)(65-45) = (15)(4.18)(20) = 1254 Joules Example 2: A 2.0 gram sample of metal requires 5.0 Joules of energy to warm from 10 to 20°C. What is the metal’s specific heat capacity? Answer: 5.0=(2.0)(C)(20-10) or 5.0=(2.0)(C)(10) and C = 0.25 J/(gx°C). Slide 19: Chemistry SOL Review— Phases of Matter Colligative Properties Adding impurities to a liquid increases the boiling point and decreases the freezing point (widens the liquid temperature range) Examples: Adding antifreeze to the water in the radiator to prevent boiling in summer and freezing in winter. Putting salt on the road to prevent the road from icing up. Slide 20: Chemistry SOL Review--Molar Relationships References http://www.markrosengarten.com/ for New York Regent’s exam powerpoint.