GAME OF Thermodynamics
BEVERLY LAM
Created on March 22, 2021
Over 30 million people build interactive content in Genially.
Check out what others have designed:
Transcript
GAME
Thermodynamics
RULES:
Roll the dice to see which tile you land on. If you land on the star, fulfill the task to stay on the tile. If unable to complete the task, move back to original location.
OF
x2
x2
x2
x3
GOAL
Using the Combined gas law, explain the relationship between volume and temperature. (Hint: As Volume ______, Temperature will ______) Combined Gas Law: P1V1/T1 = P2V2/T2
Provided with the combined gas law, explain how pressure affect the temperature. (Hint: As pressure _______, temperature will ________) Combined Gas Law: P1V1/T1 = P2V2/T2
Explain collision theory to a friend.
Which quantities must be equal for a chemical reaction at equilibrium?(1) the activation energies of the forward and reverse reactions(2) the rates of the forward and reverse reactions(3) the concentrations of the reactants and products(4) the potential energies of the reactants and products
Explain the following meme. Let your peers decide the accuracy of your response to move forward.
Systems in nature tend to undergo changes toward (1) lower energy and less randomness (2) higher energy and less randomness (3) lower energy and greater randomness (4) higher energy and greater randomness
Oh no! If we get this question wrong, we have to start at the beginning of the game: According to the following PE diagram, Which interval represents the heat of the reaction(aka enthalpy, H)?
Which statement describes the particles of an ideal gas, based on the kinetic molecular theory? (1) There are attractive forces between the particles. (2) The particles move in circular paths. (3) The collisions between the particles reduce the total energy of the gas. (4) The volume of the gas particles is negligible compared with the total volume of the gas.
BaSO4(s) Ba^(2+)(aq) SO4^(2-)(aq) What occurs when Na2SO4(s) is added to this system, increasing the concentration of SO4^(2-)(aq)?
Increasing temperature of the chemical reaction will drive the equilibrium to the _________.