Presentation is loading. Please wait.

Presentation is loading. Please wait.

May 14, 2013 AGENDA: 1 – Bell Ringer & Part. Log 2 – CN: Ideal Gas Law 3 – Practice Problem 4 – Reflection 5 – Start Ideal Gas Law HW Today’s Goal: Students.

Published byCuthbert Bates Modified over 9 years ago

Similar presentations

Presentation on theme: "May 14, 2013 AGENDA: 1 – Bell Ringer & Part. Log 2 – CN: Ideal Gas Law 3 – Practice Problem 4 – Reflection 5 – Start Ideal Gas Law HW Today’s Goal: Students."— Presentation transcript:

1

2 May 14, 2013 AGENDA: 1 – Bell Ringer & Part. Log 2 – CN: Ideal Gas Law 3 – Practice Problem 4 – Reflection 5 – Start Ideal Gas Law HW Today’s Goal: Students will be able to apply the Ideal Gas Law to solve for P, V, T, or n. Homework 1. Ideal Gas Law Practice 2. Week 34 Work is due by Friday

3 Tuesday, May 14 Objective: Students will be able to calculate using the Ideal Gas Law. Bell Ringer: Match the following parameters with their units. 1.)VolumeA.) °C + 273 2.)TemperatureB.) mL, L 3.)PressureC.) K 4.)°C  KD.) atm Please write out your answers. 5 minutes!

4 4 MINUTES REMAINING…

5 Tuesday, May 14 Objective: Students will be able to calculate using the Ideal Gas Law. Bell Ringer: Match the following parameters with their units. 1.)VolumeA.) °C + 273 2.)TemperatureB.) mL, L 3.)PressureC.) K 4.)°C  KD.) atm Please write out your answers. 4 minutes!

6 3 MINUTES REMAINING…

7 Tuesday, May 14 Objective: Students will be able to calculate using the Ideal Gas Law. Bell Ringer: Match the following parameters with their units. 1.)VolumeA.) °C + 273 2.)TemperatureB.) mL, L 3.)PressureC.) K 4.)°C  KD.) atm Please write out your answers. 3 minutes!

8 2 MINUTES REMAINING…

9 Tuesday, May 14 Objective: Students will be able to calculate using the Ideal Gas Law. Bell Ringer: Match the following parameters with their units. 1.)VolumeA.) °C + 273 2.)TemperatureB.) mL, L 3.)PressureC.) K 4.)°C  KD.) atm Please write out your answers. 2 minutes!

10 1minute Remaining…

11 Tuesday, May 14 Objective: Students will be able to calculate using the Ideal Gas Law. Bell Ringer: Match the following parameters with their units. 1.)VolumeA.) °C + 273 2.)TemperatureB.) mL, L 3.)PressureC.) K 4.)°C  KD.) atm Please write out your answers. 1 minute!!!

12 30 Seconds Remaining…

13 Tuesday, May 14 Objective: Students will be able to calculate using the Ideal Gas Law. Bell Ringer: Match the following parameters with their units. 1.)VolumeA.) °C + 273 2.)TemperatureB.) mL, L 3.)PressureC.) K 4.)°C  KD.) atm Please write out your answers. 30 seconds!!!

14 BELL- RINGER TIME IS UP!

15 May 14, 2013 AGENDA: 1 – Bell Ringer & Part. Log 2 – CN: Ideal Gas Law 3 – Practice Problem 4 – Reflection 5 – Start Ideal Gas Law HW Today’s Goal: Students will be able to apply the Ideal Gas Law to solve for P, V, T, or n. Homework 1. Ideal Gas Law Practice 2. Week 34 Work is due by Friday

16 Tuesday, May 14 Objective: Students will be able to calculate using the Ideal Gas Law. Bell Ringer: Match the following parameters with their units. 1.)VolumeA.) °C + 273 2.)TemperatureB.) mL, L 3.)PressureC.) K 4.)°C  KD.) atm Please write out your answers. REVIEW

17 Week 35 -- 5 More Weeks! Weekly Agenda Monday 5/13 – Quizzam Review Tuesday 5/14 – CN: Ideal Gas Law Wednesday 5/15 – Gas Law Passport Thursday 5/16 – Lab Friday 5/17 – Friday Funday Quizday!!

18 CHAMPS for May 14, 2013 C – Conversation – No Conversation H – Help – RAISE HAND for questions A – Activity – Ideal Gas Law M – Materials and Movement – Chem Notebook & Calculator P – Participation – Completing Notes & Starting HW S – Success – Apply the Ideal Gas Law to solve for P, V, T, or n.

19  Topic: Ideal Gas Law  Date: 5/14/2013  (P,V) are inversely related.  (P,T) and (V,T) are directly related. Combined Gas Law Boyle’s P 1 V 1 = P 2 V 2 Lussac’s P 1 = P 2 T 1 T 2 Charles’ V 1 = V 2 T 1 T 2 Combined Gas Law = P 1 V 1 = P 2 V 2 T 1 T 2

20  Topic: Ideal Gas Law  Date: 5/13/2013  Avogadro’s Principle (1811)  An observation that is an extension of KMT  All gases are assumed to have the same particle size.  Equal volume of 2 gases will have the same # of particles! Avogadro’s Principle Amedeo Avogadro For any gas: 6.02 x 10 23 particles = 22.4 L 1 mol 1 mol

21  Topic: Ideal Gas Law  Date: 5/13/2013  Ideal Gas Law relates pressure (P), volume (V), temperature (T) and number of moles (n) of gas. Ideal Gas Law P V = n R T Pressure of gas (atm) Volume of gas (L) Temp. of gas (K) Moles of gas (mol) Gas constant 0.0821 (L ·atm/mol·K )

22  Topic: Ideal Gas Law  Date: 5/13/2013 Practice Problem: A 2.0L sample of gas has a pressure of 1.5atm. If 5.0 moles occupy the sample, what is the temperature? Example PV = nRT (1.5)(2.0) = (5.0)(0.0821)x 3 = (0.4105)x 0.4105 x = 3/0.4105 x = 7.308K = T P = 1.5atm V = 2.0L n = 5.0mol R = 0.0821 L·atm/mol·K T = x

23 Reflection  In your notes answer the following question: How can you predict how a gas will be affected in a given situation? (in terms of P, V, n, and T)

Download ppt "May 14, 2013 AGENDA: 1 – Bell Ringer & Part. Log 2 – CN: Ideal Gas Law 3 – Practice Problem 4 – Reflection 5 – Start Ideal Gas Law HW Today’s Goal: Students."

Similar presentations

Ch. 14.3 – Ideal Gases -Avogadro’s Law (extension) -STP & molar volume of gas (review) -Ideal Gas Law (most important)

Ch – Ideal Gases -Avogadro’s Law (extension) -STP & molar volume of gas (review) -Ideal Gas Law (most important)
Oct. 10th AGENDA: 1 – Bell Ringer 2 – Density Lab 3 – Cornell Notes: Phase Changes 4 – Practice Problems Today’s Goal: Students will be able to contrast.

Oct. 10th AGENDA: 1 – Bell Ringer 2 – Density Lab 3 – Cornell Notes: Phase Changes 4 – Practice Problems Today’s Goal: Students will be able to contrast.
Oct. 1, 2012 AGENDA: 1 – Bell Ringer 2 – Cornell Notes: Chemical & Physical Properties; Density 3 – Demos 4 – Start Homework Today’s Goal: Students will.

Oct. 1, 2012 AGENDA: 1 – Bell Ringer 2 – Cornell Notes: Chemical & Physical Properties; Density 3 – Demos 4 – Start Homework Today’s Goal: Students will.
Pressure Conversions 1 atm = x 105 Pa 1 bar = 1 x 105 Pa

Pressure Conversions 1 atm = x 105 Pa 1 bar = 1 x 105 Pa
May 1, 2013 AGENDA: 1 – Bell Ringer & Part. Log 2 – Review HW 3 – Demo: Boyle’s Law 4 - CN: Charles’ Law 5 – Practice Problems 6 – Demo: Charles’ Law.

May 1, 2013 AGENDA: 1 – Bell Ringer & Part. Log 2 – Review HW 3 – Demo: Boyle’s Law 4 - CN: Charles’ Law 5 – Practice Problems 6 – Demo: Charles’ Law.
Gas Law Notes Chemistry Semester II Ideal Gas Law Combined Gas Law And Guy Lussac’s Law.

Gas Law Notes Chemistry Semester II Ideal Gas Law Combined Gas Law And Guy Lussac’s Law.
Gases The Ideal Gas Law.  Objectives  State the ideal gas law  Using the ideal gas law, calculate pressure, volume, temperature, or amount of gas when.

Gases The Ideal Gas Law.  Objectives  State the ideal gas law  Using the ideal gas law, calculate pressure, volume, temperature, or amount of gas when.
Topic 10 Gases III. Ideal Gas Law.

Topic 10 Gases III. Ideal Gas Law.
Temperature Unit Kelvin (K) Kelvin = °C + 273 Temperature Convert 45°C to Kelvin 45°C + 273 = 318 K.

Temperature Unit Kelvin (K) Kelvin = °C Temperature Convert 45°C to Kelvin 45°C = 318 K.
Feb. 6, 2014 AGENDA: 1 – Bell Ringer 2 – HW Check-in 3 – What’s on Tomorrow’s Quiz 4 – CN: Direct vs. Indirect Variation 5 – Work Time Today’s Goal: Students.

Feb. 6, 2014 AGENDA: 1 – Bell Ringer 2 – HW Check-in 3 – What’s on Tomorrow’s Quiz 4 – CN: Direct vs. Indirect Variation 5 – Work Time Today’s Goal: Students.
Oct. 24, 2012 Today’s Goal: Students will be able to graph temperature changes during phase changes. Homework Finish Heat Curves Practice Make up QUIZ.

Oct. 24, 2012 Today’s Goal: Students will be able to graph temperature changes during phase changes. Homework Finish Heat Curves Practice Make up QUIZ.
IDEAL GAS LAW & Avogadro’s Law What is the IDEAL GAS LAW? What are the variables involved? What is Avogadro’s Law and didn’t I already learn about him.

IDEAL GAS LAW & Avogadro’s Law What is the IDEAL GAS LAW? What are the variables involved? What is Avogadro’s Law and didn’t I already learn about him.
Ideal Gas Law & Gas Stoichiometry. Ideal Gas Law P V = n R T P = Pressure (atm) V = Volume (L) T = Temperature (K) n = number of moles R is a constant,

Ideal Gas Law & Gas Stoichiometry. Ideal Gas Law P V = n R T P = Pressure (atm) V = Volume (L) T = Temperature (K) n = number of moles R is a constant,
June 10, 2013 AGENDA: 1 – Bell Ringer 2 – Announcements 3 – CN: Calculating pH and pOH 4 – “We Do” Homework Examples 5 – “You Do” Homework Work Time Today’s.

June 10, 2013 AGENDA: 1 – Bell Ringer 2 – Announcements 3 – CN: Calculating pH and pOH 4 – “We Do” Homework Examples 5 – “You Do” Homework Work Time Today’s.
Oct. 25, 2012 AGENDA: 1 – Bell Ringer 2 – Review HW 3 – Cornell Notes: Phase Change Diagrams 4 – Practice Together 5 – Individual Practice Today’s Goal:

Oct. 25, 2012 AGENDA: 1 – Bell Ringer 2 – Review HW 3 – Cornell Notes: Phase Change Diagrams 4 – Practice Together 5 – Individual Practice Today’s Goal:
Section 13.2 Using Gas Laws to Solve Problems. Section 13.2 Using Gas Laws to Solve Problems 1.To understand the ideal gas law and use it in calculations.

Section 13.2 Using Gas Laws to Solve Problems. Section 13.2 Using Gas Laws to Solve Problems 1.To understand the ideal gas law and use it in calculations.
III. Ideal Gas Law (p. 334-335, 340-346) Ch. 10 & 11 - Gases.

III. Ideal Gas Law (p , ) Ch. 10 & 11 - Gases.
C. Johannesson III. Ideal Gas Law (p. 334-335, 340-346) Ch. 10 & 11 - Gases.

C. Johannesson III. Ideal Gas Law (p , ) Ch. 10 & 11 - Gases.
Oct. 8, 2012 AGENDA: 1 – Bell Ringer 2 – Cornell Notes: Metric to Metric Conversions 3 – Practice Problems 4 – Independent Work Time Today’s Goal: Students.

Oct. 8, 2012 AGENDA: 1 – Bell Ringer 2 – Cornell Notes: Metric to Metric Conversions 3 – Practice Problems 4 – Independent Work Time Today’s Goal: Students.
Chapter 14-3 I. Avogadro’s Principle A. Equal volumes of gases at same T and P contain equal #’s of molecules B. H 2 + Cl 2 → 2HCl 1 vol. 1 vol. 2 vol.

Chapter 14-3 I. Avogadro’s Principle A. Equal volumes of gases at same T and P contain equal #’s of molecules B. H 2 + Cl 2 → 2HCl 1 vol. 1 vol. 2 vol.

Similar presentations

Ads by Google