Gas Laws Review

Boyle

Charles

Gay-Lussac

Behavior of Gases

Miscellaneous

100

Boyle's formula for gases

P₁ xx V₁ = P₂ xx V₂

100

Charles' formula for gases

(V₁)/(T₁) = (V₂)/(T₂)

100

Gay-Lussac's formula for gases

(P₁)/(T₁) = (P₂)/(T₂)

100

The theory that defines the random movement and energy of gases

Kinetic Molecular Theory

100

The rising water experiment is an example of this gas law.

Charles' law

200

What happens on the inside of a balloon if you squeeze it

Pressure increases

200

An example of a real world experiment that shows Charles' Law

Hot air balloons, shrinking balloons, tires deflating in winter, etc.

200

A phenomenon that showcases Gay-Lussac's law

Can crush, rocket canister, exploding aerosol cans, etc.

200

The best way to decrease kinetic energy in gas particles

Decrease temperature

200

The reason gas particles are easy to compress

Open space (like air) exists between each gas particles

300

Given the following values, what is the initial pressure of this gas in atm?

P1: ?, P2: 675.1 kPa, V1: 24.4 L, V2: 46.66 L

12.74 atm

300

Charles' first name

Jacques

300

This must remain constant in order for Gay-Lussac's law to be true

Volume

300

A graphical example of the relationship between pressure and volume (please label your axis)

300

The five correct units used in the Ideal Gas formula

atm, L, mol, K,

(L xx atm)/(mol xx K)

400

An example of a real-world phenomenon or experiment that shows Boyle's Law

Marshmallows in syringes, pistons compressing air, opening a soda can, blowing up a balloon, etc.

400

Given the following values, find the missing volume in mL.

V1: ?, V2: 4.733 L, T1: 4 C, T2: 529.56 C

2000 mL

400

Three ways the pressure of a gas in an enclosed container can increase

Decreasing volume, increasing temperature, increasing the amount of gas

400

This is something gas particles do to create/maintain pressure

Collide with each other or the walls of their container

400

This gas particle moves the slowest compared to the others: H, Xe, O₂, Ne

Xe (has the largest atoms)

500

Given the following values, what is the missing Pressure in mmHg?

P1: ?, P2: 197.4 kPa, V1: 35.52 L, V2: 56,050 mL

2,337.02 mmHg

500

A diagram showing how hot air balloons work (using Charles' law)

500

Given the following values, find the missing temperature in Celsius.

P1: 8.53 atm, P2: 318 kPa, T1: 181.8 C, T2: ?

-106 C

500

Three assumptions we make about the movement of gases.

Particles have constant and random motion, there's no attractive or repulsive forces between particles, the particles move in straight lines until they collide with something

500

These are the two constants of Avogadro's gas law

Pressure and Temperature