Unit 6, Quiz #1
Your first quiz of Unit 6 will be on Thursday, March 1 and
cover material from Chapter 13 of the textbook. Quiz questions
will target the following objectives.
- Gas Pressure: To
understand gas pressure as being the result of particle collisions with
container walls, to be able to convert between the various units of gas
pressure (atm, psi, mm Hg, torr, etc.) if given unit equivalencies, and
to read an open-end or closed-end manometer.
Chapter 13.1; Chapter
13.1 Reading Guide (pp. 1-2); Nature of a Gas (pp. 3-4)
- Gas Variables and Proportional Reasoning: To
inspect a data set or a graphical representation for a relationship
between two gas variables and to identify an appropriate conclusion and
associated evidence reagrding the relationship and to use the
relationship to make a prediction about the effect that one gas
variable (P, T, V, or n) has upon another gas variable.
Resources: Lab SLG1 (Pressure and Volume); Lab SLG2 (Pressure and Temperature); Gas Law Concepts (pp. 9-12)
- Two-State Gas Law Calculations: To
use Charles' Law, Boyle's Law, Avogadro's Law, John's Law and the
combined gas law to solve problems for the unknown quantity of a given
Chapter 13.2-4; Chapter 13.2-4 Reading Guide (pp. 5-6); Gas Law Calculations (pp. 13-17); Lab SLG3 (Molar Volume of a Gas)
- Ideal Gas Law and Dalton's Law: To
use the ideal gas law and Dalton's law to analyze gaseous systems and
predict and unknown quantity from knowledge of other variables.
Chapter 13.5-6; Chapter 13.5-6 Reading Guide (pp. 7-8); Gas Law Calculations (pp. 13-17)
- Gas Stoichiometry: To
use the molar volume of a gas at STP or the ideal gas law to solve
stoichiometry problems for gaseous reactants and products at standard
and non-standard pressure and temperature conditions.
Resources: Gas Stoichiometry (pp. 25-28)
- Kinetic Theory of Gases: To use the Kinetic Theory of Gases to explain at the particle level why the various gas laws (PV=k, P/T=k, V/T=k) exist.
Read Chapter 13.7-9; Chapter 13:7-9 Reading Guide (p. 19); ChemThink:
Gas Behavior (pp. 21-22), Kinetic Theory of Gases (pp. 23-24)