[GENERAL CHEMISTRY] Gas Laws

a. Boyle's/Mariotte

[GAS LAWS]

Gas law with constant temperature.

a. Boyle's/Mariotte Law

b. Charles' Law

c. Gay-Lussac's Law

d. Combined Gas Law

e. Ideal Gas Law

b. Charles

[GAS LAWS]

Gas law with constant pressure.

a. Boyle's/Mariotte Law

b. Charles' Law

c. Gay-Lussac's Law

d. Combined Gas Law

e. Ideal Gas Law

c. Gay-Lussac's

[GAS LAWS]
Gas law with constant volume.

a. Boyle's/Mariotte Law

b. Charles' Law

c. Gay-Lussac's Law

d. Combined Gas Law

e. Ideal Gas Law

a. Boyle's/Mariotte

[GAS LAWS]
P1V1 = P2V2

a. Boyle's/Mariotte Law

b. Charles' Law

c. Gay-Lussac's Law

d. Combined Gas Law

e. Ideal Gas Law

a. Boyle's/Mariotte Law

[GAS LAWS]
P∝ (1/V)

a. Boyle's/Mariotte Law

b. Charles' Law

c. Gay-Lussac's Law

d. Combined Gas Law

e. Ideal Gas Law

b. Charles' Law

[GAS LAWS]
T1/V1 = T2/V2

a. Boyle's/Mariotte Law

b. Charles' Law

c. Gay-Lussac's Law

d. Combined Gas Law

e. Ideal Gas Law

b. Charles' Law

[GAS LAWS]
V∝T

a. Boyle's/Mariotte Law

b. Charles' Law

c. Gay-Lussac's Law

d. Combined Gas Law

e. Ideal Gas Law

c. Gay-Lussac's Law

[GAS LAWS]
P1/T1 = P2/T2

a. Boyle's/Mariotte Law

b. Charles' Law

c. Gay-Lussac's Law

d. Combined Gas Law

e. Ideal Gas Law

c. Gay-Lussac's Law

[GAS LAWS]
P∝T

a. Boyle's/Mariotte Law

b. Charles' Law

c. Gay-Lussac's Law

d. Combined Gas Law

e. Ideal Gas Law

d. Combined Gas Law

[GAS LAWS]
P1V1/T1 = P2V2/T2

a. Boyle's/Mariotte Law

b. Charles' Law

c. Gay-Lussac's Law

d. Combined Gas Law

e. Ideal Gas Law

e. Ideal Gas Law

[GAS LAWS]

PV = nRT

a. Boyle's/Mariotte Law

b. Charles' Law

c. Gay-Lussac's Law

d. Combined Gas Law

e. Ideal Gas Law

f. All

[GAS LAWS]
Units in gas law:

a. Pressure in atm

b. Volume in L

c. Temperature in K

d. a and b

e. b and c

f. All

a. 0.08205 L•atm/mol•K

[GAS LAWS]
In ideal gas law, R (Universal gas constant) is equal to:

a. 0.08205 L•atm/mol•K

b. 0.08207 L•atm/mol•K

c. 0.08105 L•atm/mol•K

d. 0.08107 L•atm/mol•K

e. b and c

STP:

a) T = 273.15 K

b) P = 1 atm

c) V = 22.4 L

[GAS LAWS]

At standard temperature and pressure (STP):

a. T = 273.15 °C

b. P = 1 atm

c. V = 22.4 L

d. a and b

e. b and c

f. All

a. Avogadro's Principle

[GAS LAWS]
Equal volumes of different gases have same no. of moles at STP.

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Fick's 1st Law

e. Henry's Law

a. Avogadro's Principle

[GAS LAWS]
V1/n1 = V2/n2

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Fick's 1st Law

e. Henry's Law

a. Avogadro's Principle

[GAS LAWS]

V/n = 6.022 X 10^23

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Fick's 1st Law

e. Henry's Law

a. Avogadro's Principle

[GAS LAWS]
V∝n

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Fick's 1st Law

e. Henry's Law

c. 6.022 X 10^23

[GAS LAWS]

Avogadro's number

a. 6.021X 10^23

b. 6.021X 10^-23

c. 6.022 X 10^23

d. 6.022 X 10^-23

c. Dalton's Law of Partial Pressure

[GAS LAWS]
Total pressure in a mixture (non-interacting gases) is equal to the sum of the partial pressures of each gas.

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Fick's 1st Law

e. Henry's Law

c. Dalton's Law

[GAS LAWS]
PT = P1 + P2 + P3

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Fick's 1st Law

e. Henry's Law

b. Graham's Law

[GAS LAWS]
Rate of effusion (diffusion) and speed of gas are inversely proportional to the square root of their density providing the temperature and pressure are same for 2 gases.

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Fick's 1st Law

e. Henry's Law

a. Diffusion

[GAS LAWS]
Rate at which 2 gases mix.

a. Diffusion

b. Effusion

a. Diffusion

[GAS LAWS]
Gradual mixing of molecules of one gas w/ the molecules of another gas by virtue of their kinetic properties

a. Diffusion

b. Effusion

b. Effusion

[GAS LAWS]

Rate at which gas escapes through a pinhole vacuum.

a. Diffusion

b. Effusion

b. Effusion

[GAS LAWS]
Passage of a gas under pressure through a small opening

a. Diffusion

b. Effusion

c. Both true

[GAS LAWS]
e1) H2 is relatively smaller thus diffuse faster

2) O2 is relatively larger thus diffuse slower

a. Only 1 is true

b. Only 2 is true

c. Both true

d. Both false

d. Fick's 1st Law

[GAS LAWS]
Diffusion rate (flux) of liquid or gas is directly proportional to the concentration gradient (from high concentration to low concentration).

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Fick's 1st Law

e. Henry's Law

e. Henry's Law

[GAS LAWS]
As there is decrease in temperature, increase pressure (i.e., sealed container), more CO2 is dissolved in water.

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Fick's 1st Law

e. Henry's Law

b. Decrease temperature - and increase pressure

[GAS LAWS]
In Henry's law, which will lead to more CO2 dissolved in water.

a. Decrease pressure

b. Decrease temperature

c. Increase temperature

d. a and b

e. a and c

f. All

e. Henry's Law

[GAS LAWS]
Pressure ∝ Solubility

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Fick's 1st Law

e. Henry's Law

d. Real Gas Equation

[GAS LAWS]
Equation of state which extends the ideal gas law to include the effects of interaction between molecules of a gas, as well as accounting for the finite size of the molecules.

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Real Gas Equation

e. Raoult's Law

d. Real Gas Equation

[GAS LAWS]
Van der Waals equation

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Real Gas Equation

e. Raoult's Law

e. Raoult's Law

[GAS LAWS]
Psolution = Xsolvent Psolvent

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Real Gas Equation

e. Raoult's Law

e. Raoult's Law

[GAS LAWS]
States that the vapor pressure of a solvent above a solution is equal to the vapor pressure of the pure solvent at the same temperature scaled by the mole fraction of the solvent present.

a. Avogadro's Principle

b. Graham's Law

c. Dalton's Law

d. Real Gas Equation

e. Raoult's Law