Lecture 1: Energy and Enthalpy Reading: Zumdahl 9.1 and 9.2 Outline –Energy: Kinetic and Potential –System vs. Surroundings –Heat, Work, and Energy –Enthalpy.

Slides:



Advertisements
Similar presentations
Energy Thermodynamics-study of energy and its interconversions Labs
Advertisements

Lecture 1: Energy Reading: Zumdahl 9.1 Outline –Energy: Kinetic and Potential –System vs. Surroundings –Heat, Work, and Energy.
Chapter 6 Thermochemistry -study of heat changes that occur during chemical reactions, study of relationships between chemistry and energy energy- ability.
Energy.
AP CHEMISTRY CHAPTER 6 NOTES THERMOCHEMISTRY
Thermochemistry Chapter 5 Thermochemistry John D. Bookstaver St. Charles Community College St. Peters, MO  2006, Prentice Hall, Inc. Chemistry, The Central.
Thermochemistry Chapter 6
Chapter 7 Thermochemistry.
Chapter 6 Thermochemistry
Thermochemistry Energy The ability to do work or transfer heat.  Work: Energy used to cause an object that has mass to move.  Heat: Energy used to cause.
Lecture 2: Enthalpy Reading: Zumdahl 9.2, 9.3 Outline –Definition of Enthalpy (  H) –Definition of Heat Capacity (C v and C p ) –Calculating  E and.
THERMOCHEMISTRY ENERGY CHANGES ASSOCIATED WITH CHEMICAL REACTION.
Lecture 1: Energy Reading: Zumdahl 9.1 Outline –Energy: Kinetic and Potential –System vs. Surroundings –Heat, Work, and Energy.
Lecture 2: Enthalpy Reading: Zumdahl 9.2, 9.3 Outline –Definition of Enthalpy (  H) –Definition of Heat Capacity (C v and C p ) –Calculating  E and.
Energy Relationships in Chemical Reactions Chapter 6 Dr. Ramy Y. Morjan.
6–16–1 Ch. 6 Thermochemistry The relationship between chemistry and energy Basic concept of thermodynamics Energy conversion: Energy: the capacity to do.
Prentice-Hall © 2007 General Chemistry: Chapter 7 Slide 1 of 58 CHEMISTRY Ninth Edition GENERAL Principles and Modern Applications Petrucci Harwood Herring.
THERMODYNAMICS Courtesy of lab-initio.com. Definitions #1 Energy: The capacity to do work or produce heat Potential Energy: Energy due to position or.
Thermodynamics Chapter 5 Thermochemistry. Thermodynamics – study of energy and its transformation. Thermochemistry – relationship of energy changes in.
Thermochemistry Chapter 6.
1 Chapter 6 EnergyThermodynamics. 2 Energy is... n The ability to do work. n Conserved. n made of heat and work. n a state function. n independent of.
Energy. ___________ – the ability to do work or produce heat Energy exists in two different forms – ___________ energy & ___________ energy.
Plan for Wed, 15 Oct 08 Lecture –The nature of energy (6.1) –Enthalpy and calorimetry (6.2)
Chapter 6 Energy Relationships in Chemical Reactions Nature and types of energy First law of thermodynamics Thermochemistry Enthalpy.
Thermochemistry. Energy In this topic, we are interested in energy transfers Types of energy Definition: energy is the capacity to do work Kinetic energy.
General Chemistry M. R. Naimi-Jamal Faculty of Chemistry Iran University of Science & Technology.
Thermodynamics They study of energy and its transformations.
Review First Law. Work Work is energy transferred when directed motion is achieved against an external force. There are many types of forces available.
Thermochemistry The heat of the matter. Energy The capacity to do work or produce heat.
Thermochemistry Chapter 6. The Nature of Energy Energy is the capacity to do work or produce heat. Energy is the capacity to do work or produce heat.
THERMOCHEMISTRY Courtesy of lab-initio.com. Definitions #1 Energy: The capacity to do work or produce heat. Potential Energy: Energy due to position or.
Thermochemistry © 2009, Prentice-Hall, Inc. Chapter 16 Thermochemistry.
Chapter 6 Thermochemistry. 6.1: I. Nature of Energy A. Energy (E): capacity for work or producing heat B. Law of Conservation of Energy: can’t be created.
Chapter Thermochemistry. Thermo means heat or energy Energy: Capacity of doing work Work: Force x displacement.
THERMOCHEMISTRY ENERGY CHANGES ASSOCIATED WITH CHEMICAL REACTION.
Chapter 10 Energy. 10 | 2 Energy and Energy Changes Energy: ability to do work or produce heat –Chemical, mechanical, thermal, electrical, radiant, sound,
Thermochemistry © 2009, Prentice-Hall, Inc. Chapter 11 Thermochemistry.
Thermochemistry Chapter 6 Thermochemistry. Thermochemistry Energy The ability to do work or transfer heat.  Work: Energy used to cause an object that.
Thermochemistry Chapter 5 Thermochemistry. Thermochemistry Energy The ability to do work or transfer heat.  Work: Energy used to cause an object that.
Chapter 5 Thermochemistry -relationship between chemical reactions and energy changes energy- capacity to do work or transfer heat work- energy used to.
An Introduction into Thermodynamics Advanced Chemistry Ms. Grobsky.
Thermochemistry AP Chemistry. thermodynamics: the study of energy and its transformations -- thermochemistry: the subdiscipline involving chemical reactions.
Chapter 6 – Thermochemistry. A.The chemistry related to heat change in chemical reactions 1.Energy – ability to do work or produce heat work = force x.
Thermochemistry Chapter 6 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. PowerPoint Lecture Presentation.
Energy Thermodynamics
Thermochemistry. Key terms Thermodynamics – study of energy and its interconversions Energy – capacity to do work or produce energy Law of conservation.
Chapter 5 Thermochemistry. Energy Energy is the ability to do work or transfer heat. –Energy used to cause an object that has mass to move is called work.
Thermochemistry © 2009, Prentice-Hall, Inc. Chapter 5 Thermochemistry John D. Bookstaver St. Charles Community College Cottleville, MO Chemistry, The Central.
Thermochemistry. Thermodynamics Study of energy transformations Thermochemistry is a branch of thermodynamics which describes energy relationships in.
THERMOCHEMISTRY ENERGY CHANGES ASSOCIATED WITH CHEMICAL REACTION.
Thermochemistry Thermodynamics = study of energy and its transformations Thermochemistry = study of chemical reactions involving changes in heat energy.
Energy Relationships in Chemical Reactions. The nature of Energy and Types of Energy Energy – The capacity to do work Chemists define work as directed.
Energy The capacity to do work or to produce heat.
Chapter 5 Thermochemistry John D. Bookstaver St. Charles Community College Cottleville, MO Lecture Presentation © 2012 Pearson Education, Inc.
Copyright©2000 by Houghton Mifflin Company. All rights reserved. 1 Chemistry FIFTH EDITION by Steven S. Zumdahl University of Illinois.
Thermochemistry Chapter 5 Thermochemistry John D. Bookstaver St. Charles Community College St. Peters, MO  2006, Prentice Hall, Inc. Chemistry, The Central.
Chapter 5 Thermochemistry John D. Bookstaver St. Charles Community College Cottleville, MO Lecture Presentation © 2012 Pearson Education, Inc.
Thermochemistry. Thermodynamics - study of energy and its transformations Thermochemistry - study of chemical reactions involving changes in heat.
Energy. Energy is classified: Kinetic energy – energy of motion Potential energy – energy of position Both energies can be transferred from one object.
Define internal energy, work, and heat. internal energy: Kinetic energy + potential energy Heat: energy that moves into or out of the system because of.
Thermochemistry © 2009, Prentice-Hall, Inc. Thermochemistry.
First Law of Thermodynamics
Thermochemistry Chapter 6.
Chapter 5 Thermochemistry
Chapter 6 Thermochemistry.
Chapter 6: Thermochemistry
THERMOCHEMISTRY Courtesy of lab-initio.com.
Energy Review.
Presentation transcript:

Lecture 1: Energy and Enthalpy Reading: Zumdahl 9.1 and 9.2 Outline –Energy: Kinetic and Potential –System vs. Surroundings –Heat, Work, and Energy –Enthalpy

Energy is the capacity to do work or to produce heat Energy is conserved, it can neither be created nor destroyed, different forms of energy interconvert However, the capacity to utilize energy to do work is limited (entropy)

Energy: Kinetic vs. Potential Potential Energy (PE) –Energy due to position or chemical composition –Equals (mgh) in example. Kinetic Energy (KE) –Energy due to motion. –Equals mv 2 /2 in example.

Mechanical Energy = KE + PE Energy is the sum of kinetic energy and potential energy. Energy is readily interconverted between these two forms. If the system of interest is isolated (no exchange with surroundings), then total energy is constant.

Example: Mass on a Spring Initial PE = 1/2 kx 2 At x = 0: –PE = 0 –KE = 1/2mv 2 =1/2kx 2 Units of Energy Joule = kg.m 2 /s 2 Example: –Init. PE = 10 J –M = 10 kg –Vmax = [2(PE)/M] 1/2 = 1.4m/s 0

Energy: Kinetic vs. Potential Potential Energy (PE) –Energy due to position or chemical composition –Equals (mgh) in example. Kinetic Energy (KE) –Energy due to motion. –Equals mv 2 /2 in example.

First Law of Thermodynamics First Law: Energy of the Universe is Constant E = q + w q = heat. Transferred between two bodies of differing temperature. Note: q ≠ Temp! w = work. Force acting over a distance (F x d)

Applying the First Law Need to differentiate between the system and surroundings. System: That part of the universe you are interested in (i.e., you define it). Surroundings: The rest of the universe.

Conservation of Energy Total energy is conserved. Energy gained by the system must be lost by the surroundings. Energy exchange can be in the form of q, w, or both.

Heat Exchange: Exothermic Exothermic Reaction. Chemical process in which system evolves resulting in heat transfer to the surroundings Heat flows out of the system q < 0 (heat is lost)

Another Example of Exothermic

Heat Exchange: Endothermic Endothermic Reaction: Chemical process in which system evolves resulting in heat transfer to the system Heat flows to the system q > 0 (heat is gained)

Another Example of Endothermic

In exothermic reactions, the potential energy stored in chemical bonds is converted into thermal energy (random kinetic energy), i.e. heat Once we have done that, we have lost the ability to utilize the same potential energy to do work or generate heat again (dissipation)

Energy and Sign Convention If system loses energy: E final < E initial E final -E initial =  E < 0. If system gains energy: E final > E initial E final -E initial =  E > 0.

Heat and Work Sign Convention If system gives heat q < 0 (q is negative) If system gets heat q > 0 (q is positive) If system does work w < 0 (w is negative) If work done on system w > 0 (w is positive)

Example: Piston Figure 9.4, expansion against a constant external pressure No heat exchange: q = 0 System does work: w < 0 (adiabatic)

Example (cont.) How much work does the system do? P ext = force/area |w| = force x distance = P ext x A x  h = P ext  V w = - P ext  V (note sign)

When it is compressed, work is done to a gas When it is expanded, work is done by the gas (e.g. your car’s engine)

Example 9.1 A balloon is inflated from 4 x 10 6 l to 4.5 x 10 6 l by the addition of 1.3 x 10 8 J of heat. If the balloon expands against an external pressure of 1 atm, what is  E for this process? Ans: First, define the system: the balloon.

Example 9.1 (cont.)  E = q + w = (1.3 x 10 8 J) + (-P  V) = (1.3 x 10 8 J) + (-1 atm (V final  V init )) = (1.3 x 10 8 J) + (-0.5 x 10 6 l.atm) Conversion: J per l x atm (-0.5 x 10 6 l.atm) x (101.3 J/l.atm) = -5.1 x 10 7 J

Example 9.1 (cont.)  E = (1.3 x 10 8 J) + (-5.1 x 10 7 J) = 8 x 10 7 J (Ans.) The system gained more energy through heat than it lost doing work. Therefore, the overall energy of the system has increased.

Definition of Enthalpy Thermodynamic Definition of Enthalpy (H): H = E + PV E = energy of the system P = pressure of the system V = volume of the system

Why we need Enthalpy? Consider a process carried out at constant pressure. If work is of the form  PV), then:  E = q p + w = q p - P  V  E + P  V = q p q p is heat transferred at constant pressure.

Definition of Enthalpy (cont.) Recall: H = E + PV  H =  E +  PV) =  E + P  V (P is constant) = q p Or  H = q p The change in enthalpy is equal to the heat transferred at constant pressure.

Changes in Enthalpy Consider the following expression for a chemical process:  H = H products - H reactants If  H >0, then q p >0. The reaction is endothermic If  H <0, then q p <0. The reaction is exothermic

Enthalpy Changes Pictorially Similar to previous discussion for Energy. Heat comes out of system, enthalpy decreases (ex. Cooling water). Heat goes in, enthalpy increases (ex. Heating water)