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Chapter 6 - Gases
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Physical Characteristics of Gases
Although gases have different chemical properties, gases have remarkably similar physical properties. Gases always fill their containers (recall solids and liquids). No definite shape and volume Gases are highly compressible: Volume decreases as pressure increases Volume increases as pressure decreases Gases diffuse (move spontaneously throughout any available space). Temperature affects either the volume or the pressure of a gas, or both.
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Definition of a Gas Therefore a definition for gas is: a substance that fills and assumes the shape of its container, diffuses rapidly, and mixes readily with other gases.
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Three Gas Laws Pressure force of colliding particles per unit area
According to the KMT gases exert pressure due to the forces exerted by gas particles colliding with themselves and the sides of the container SI unit for pressure is kilopascals - kPa
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1 kPa = 1000 N/ 1 m2 Atmospheric pressure – pressure exerted by air particles colliding SATP – 100 kPa at 25 °C STP – kPa at 0 °C
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Boyle’s Law As pressure on a gas increases the volume of the gas decreases proportionally as the temperature is held constant P1V1 = P2V2
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Charles Law the volume of a gas increases proportionally as the temperature of the gas increases, if the pressure is held Constant V1 = V2 T1 T2
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Boyle’s Law – inverse relationship Charles Law – direct relationship
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Kelvin Temperature Scale
Temperature - the average kinetic energy of the particles making up a substance Kelvin Temp Scale: based of absolute zero — all kinetic motion stops 273°C = K °C = 273 K °C =303 K °C = 253 K Formulas °C = K K= °C+273
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Combined Gas Law This is when all variables (T,P, and V) are changing
P1V1 = P2V2 T T2
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Avogadro’s Theory and Molar volume
The kinetic molecular theory is strongly supported by experimental evidence. The K M theory explains why gases, unlike solids and liquids, are compressible. The K M theory explains the concept of gas pressure. The K M theory explains Boyle’s Law — Increase volume \ decrease pressure The KM theory explains Charles’ Law Increase volume \ increase temperature
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History Lesson 1808 – Joseph Guy – Lussac 1810 – AmadeoAvogadro
“Law of Combining Volumes” When measuring at the same temp and pressure, volumes of gas reactants and products (in chemical reactions) are always in simple whole number ratios 1810 – AmadeoAvogadro “Avogadro’s Theory” Equal volumes of gases at the same temp and pressure have equal number of molecules
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Molar Volume of Gases “new conversion ratio”
Avogadro says : T1 = T2 P1 =P2 V1 = V2 Then # particles of gas 1 = # particles of gas 2 1 mol = 6.03 x particles Lets put these two ideas together……
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Therefore for all gases at a specific temp and pressure there must be a certain volume that contains exactly 1 mole of particles - molar volume The two most standard temps and pressures are STP and SATP
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Molar Volume When gases are at STP: When gases are at SATP:
1 mole of any gas = 22.4 L/mol When gases are at SATP: 1 mole of any gas = 24.8 L/mol
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Ideal Gas Equation Ideal Gas — is a hypothetical gas that obeys all the gas laws perfectly under all conditions. It is composed of particles with no attraction to each other. (Real gas particles do have a tiny attraction) The further apart the gas particles are, the faster they are moving the less attractive force they have and behave the most like ideal gases The smaller the molecules the closer the gas resembles an ideal gas We assume ideal gases always. .
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Equation PV = nRT P = pressure (kPa)
V = volume (L) n = moles (mol) R = universal gas constant (8.31 kPa*L ) Mol * K T = temperature (K) Sometimes the n must be converted to mass after the equation is completed. If this is necessary, use a conversion
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