Quiz on Homework 10 and 11 1.For what purpose is a manometer used? 2.Explain how a gas exerts pressure on its container. 3.Which gas exerts less pressure,

Slides:

Advertisements

Similar presentations

Learning about the special behavior of gases

Advertisements

Chapter 13 Gas Laws.

Kinetic Theory and a Model for Gases What is the kinetic theory of matter, and what are the three assumptions of the kinetic theory as it applies to gases?

The Nature of Gases. All gases exhibit remarkably similar physical behavior Pure gases and mixtures behave the same! A mole of methane (CH 4 ) in a balloon.

I. Physical Properties Ch 12.1 & 13 Gases. Kinetic Molecular Theory 1. Particles of matter are ALWAYS in motion 2. Volume of individual particles is 

Gas Properties and Laws Explains why gases act as they do. Assumptions/Postulates of the theory 1. Gases are composed of small particles. 2.These particles.

Slide 1 of 29 © Copyright Pearson Prentice Hall > The Nature of Gases Kinetic Theory and a Model for Gases The word kinetic refers to motion. The ___________.

Gasses Kinetic molecular theory Pressure. Introduction Earth’s atmosphere is a gaseous solution composed of mostly nitrogen and oxygen The atmosphere.

Kinetic Molecular Theory & Gas Laws. Kinetic Theory of Gases  Gases exert pressure because their particles frequently collide with the walls of their.

1 Gases Chapter Properties of Gases Expand to completely fill their container Take the Shape of their container Low Density –much less than solid.

Chapter 13 States of Matter

Chapter 13 Gases. Chapter 13 Table of Contents Copyright © Cengage Learning. All rights reserved Pressure 13.2 Pressure and Volume: Boyle’s Law.

Ch. 13 States of Matter Ch The Nature of Gases.

Chemistry Chapter 10 notes Physical Characteristics of Gases.

The Nature of Gases Regardless of their chemical identity,

Chapter 13 States of Matter.

Chapter 13: States of Matter

The Gas Laws The density of a gas decreases as its temperature increases.

STATES OF MATTER Chemistry CP.

The Properties of Gases. Properties of Gases 1. Gases expand to fill the container. 2. Gases take on the shape of the container. 3. Gases are highly compressible.

The Property of Gases – Kinetic Molecular Theory And Pressure.

THE NATURE OF GASES SECTION 10.1 After reading Section 10.1, you should know: the three assumptions of the kinetic theory how to convert pressure readings.

Gases. Characteristics of Gases Gases are fluids Gases are fluids –In other words, they can flow. Gases have low density Gases have low density –Most.

Chemistry 20 Chapter 3 PowerPoint presentation by R. Schultz

Gas Laws Boyle ’ s Law Charles ’ s law Gay-Lussac ’ s Law Avogadro ’ s Law Dalton ’ s Law Henry ’ s Law 1.

The Gas Laws A Tutorial on the Behavior of Gases..

Chapter 13 Kinetic - Molecular Theory. The Nature of Gases The word “Kinetic” means motion The energy an object has due to its motion is called kinetic.

Chapter 11 The Nature of Gases & Measuring Gases Pages

Kinetic Theory and a Model for Gases The word kinetic refers to motion. The energy an object has because of its motion is called kinetic energy. According.

Kinetic Theory All matter consist of small particles. All matter consist of small particles. The molecules are in constant, random, rapid motion. The.

Slide 1 of 29 © Copyright Pearson Prentice Hall > The Nature of Gases Kinetic Theory and a Model for Gases The word kinetic refers to motion. The energy.

1 Gases Mr. Wally Chemistry. 2 Kinetic Theory of Gases ► Molecules in random motion: strike each other and walls of container. ► Force exerted on walls.

UNIT 5: GASES & ATMOSPHERIC CHEMISTRY 11.1, 11.2 – The Basics of KMT and Pressure.

Chapter 13 Notes Kinetic Molecular Theory. Kinetic Theory and Gases Kinetic Energy—Energy that an object has due to motion. The Kinetic Theory states:

Quiz 5/4/04 For what purpose is a manometer used?

1.Which process represents fusion? Which process represents condensation? Which process represents vaporization? 1234.

 Kinetic= motion  All matter consists of small particles  The molecules are in constant, random, rapid motion  All collisions are elastic (no net.

KINETIC MOLECULAR THEORY Physical Properties of Gases: Gases have mass Gases are easily compressed Gases completely fill their containers (expandability)

Properties of Gases.

Warmup 11/20/15 Describe a gas. What's it actually made of? How does it work? Objective Tonight’s Homework To learn how we model a gas physically pp 382:

Particle Theory of Matter

Gases and their Properties. Kinetic-Molecular Theory Gases = large #’s of tiny particles spaced far apart Gases = large #’s of tiny particles spaced far.

Pressure. The amount of force an object puts on a surface. Pressure is measured by a barometer. Atmospheric pressure comes from air being pulled down.

Absolute Zero Theoretical temperature of a gas when its pressure is zero Kelvin scale – temperature scale where 0 K is absolute zero One degree change.

Vocabulary: Due Monday 1.kinetic 2.kinetic energy 3.kinetic theory 4.force 5.intermolecular force 6.molecule 7.motion 8.substance 9.particle 10. solid.

States of Matter and Gases Unit 9. The States of Matter Solid: material has a definite shape and definite volume Solid: material has a definite shape.

GAS LAWS. The Nature of Gases  Gases expand to fill their containers  Gases are fluid – they flow  Gases have low density  1/1000 the density of the.

Unit 7 ~ Gases (Chapter 13) And you. 7-1 Introduction (Section 13.1) There are many variables needed to adequately describe the conditions of a gas 1)

The Property of Gases – Kinetic Molecular Theory explains why gases behave as they do

13.1 The Nature of Gases > 1 Copyright © Pearson Education, Inc., or its affiliates. All Rights Reserved. Chapter 13 States of Matter 13.1 The Nature of.

Slide 1 of 29 Chemistry © Copyright Pearson Prentice Hall Slide 2 of 29 The Nature of Gases The skunk releases its spray! Within seconds you smell.

THE KINETIC THEORY AND THE STATES OF MATTER 1. What’s happening when the food coloring is dropped into the beaker of water? 2. What is it called? 3.

Gas Laws Compressible They have no constant volume. *They fill the container they are placed in. They have mass. They have high Kinetic energy (KE = ½.

Unit 5: Gas Chemistry (5.5) Solving Gas Pressure Problems.

Unit 7 ~ Gases (Chapter 13).

Behavior of Gases.

Directions Use this powerpoint to fill in notes on properties of gases

I. Physical Properties (p )

Adv: Agenda Do Now: Take out computer

Kinetic-Molecular Theory and Gases

The Nature of Gases.

Kinetic Theory and a Model for Gases

States of Matter Gases, Liquids, Solids.

Directions Use this powerpoint to fill in notes on properties of gases

Chapter 13 States of Matter 13.1 The Nature of Gases

Northwestern High School

States of Matter.

Chapter 13.1 The Nature of Gases.

Chemistry/Physical Setting

Presentation transcript:

Quiz on Homework 10 and 11 1.For what purpose is a manometer used? 2.Explain how a gas exerts pressure on its container. 3.Which gas exerts less pressure, the one on the right or the left? 4.What is the value of standard atmospheric pressure in kPa. 5.If the difference in height in the manometer on the left is 75mm, and atmospheric pressure is 100 kPa, what is the pressure of the gas in the left manometer? Gas molecules bounce against the sides of the container, Pressure = Force/Area therefore, the more collisions, the more pressure. A manometer is used to measure gas pressure kPa The gas on the left exerts less pressure P gas = 100 – 75/7.5 P gas = 90 kPa

Due: HW 11: Define and draw a labeled diagram of a manometer and a barometer. Take notes on page 381 sample problem; Do #1-8 page 382 Due: HW #12: Do #25  28 and 40 page 390 and 391. If you have trouble deciding when to add, and when to subtract atmospheric pressure, first draw a sketch of the manometer. Add atmospheric pressure if gas pushes more than atmosphere. Due: HW #13 Notes page 384  385; Do #29, 30 page 391 Due Tomorrow: HW 14 # 32,33,34 page 391 Due Wednesday: HW 15: Notes page 385; Do # 16 p 388; #35,43 page 391 Extra Credit: #44,45,46, 48,49,50 page 392 (20 pts) (label it HW #16) Whatever is not done in class is due Friday, April 30. HW 14 Due Tuesday, Test Wed. P atm – h/7.5 P atm + h/7.5

How do you solve these problems? 1.An open manometer, such as the one in figure 15.4, is filled with mercury and connected to a container of hydrogen. The mercury level is 62 mm higher in the arm of the tube connected to the gas. Use this model ( P atm - ht/7.5) kPa Atmospheric pressure is 97.7 kPa. What is the pressure of the hydrogen in kilo pascals? P atm – ht/ kPa – (62mm / 7.5kPa/mm) = 97.7 kPa – 8.3 kPa = 89.4 kPa

Temperature and Heat Temperature is the average kinetic energy of molecules. Absolute zero is o C, -273 o C. To convert from Celsius to Kelvin add 273 To convert to Celsius subtract 273. One Celsius degree = 1 Kelvin degree!

Do #9- 12 in class 9. a. 86K b. 191 K c. 533 K d. 321 K e. 894 K = -187 o C = - 82 o C = 260 o C = 48 o C = 621 o C - 273K 10. a. 23 o C b. 58 o C c. -90 o C d. 18 o C e. 25 o C + 273K = 296 K + 273K = 331 K + 273K = 183 K + 273K = 291 K + 273K = 298 K 11 a. 559 o C b. 417 o C c. 111 o C d o C e. – 213 o C 12. N 2 = 28g/mole F 2 = 38 g/mole CO 2 = 44g/mole O 2 = 32 g/mole N2 N2 moves the fastest because it weighs the least.

States of matter Gases move rapidly filling the entire container. Gases form when atoms do not have enough attractive force to stay near each other. Liquids consist of disorganized atoms/molecules which are attracted to each other. Solids are organized structures with lots of attraction and little “freedom” to move most movement least movement

How do you solve problems with closed end manometers or barometers? 2. A closed manometer, like the one in figure 15.4, is filled with mercury and connected to a container of nitrogen. The difference in the height of mercury in the two arms is 691 mm. What is the pressure of the nitrogen in kilopascals? 691 mm / 7.5 mm/kPa Since the “other side” has a pressure of zero, adding or subtracting changes nothing! P nitrogen = 92.1 kPa

How do you solve these problems? 3. An open manometer connected to a tank of argon has a mercury level 38 mm higher in the atmospheric arm. Use this model ( P atm + ht/7.5) kPa If Atmospheric pressure is 96.3 kPa, what is the pressure of Argon in kPa? P atm + ht/ kPa + (38mm / 7.5kPa/mm) = 96.3 kPa – 5.1 kPa = kPa

Answers to homework page (1/2 credit if the work is not shown) kPa kPa kPa kPa 5. All matter is composed of small particles; these particles are in constant motion; all collisions between particles are perfectly elastic. 6. Gas molecules collide with the walls of the container holding the gas, and each collision exerts a force on the container. The force of collision and the number of collisions cause pressure. 7. In an open-arm manometer one arm of the U-tube is open to the atmosphere. The gas being studied exerts pressure on the other arm. In a closed-arm manometer, there is a vacuum above the liquid in one arm. If a closed-arm manometer is used to measure atmospheric pressure, it is called a barometer. An open-arm manometer measures the difference in pressure between the atmosphere and the gas sample. A closed-arm manometer measures pressure independently of atmospheric pressure kPa; 10.7 kPa

# 27. An open manometer like the one in figure 15.4 is used to measure the pressure of a gas sample. The mercury level is 24 mm higher in the arm open to the atmosphere What is the pressure, in kilopascals, of the gas in the container if the air pressure is kilopascals? P atm = /7.5 P atm = 103.5kPa

# 26. In a closed manometer, assume that the height of the levels differs by 522 mm Hg. What is the pressure, in kilopascals, of the gas in the container? P gas = 522/7.5 P gas = 69.6 kPa Answers to the rest of the questions are: kPa kPa 29. The temperature increases directly (proportionally) with an increase in Kinetic energy. 30. Absolute zero means all molecular motion ceases (stops). Homework where work is shown only merits ½ credit!