Heating curves and  H temperature added energy. Heating curves and  H temperature added energy solidliquidgas.

Slides:

Advertisements

Similar presentations

What happens when we add energy to a solid at constant pressure gas.

Advertisements

Phase Changes and their Calculations

A-B = Solid ice, temperature is increasing. Particles gain kinetic energy, vibration of particles increases. Heating and cooling curve for water heated.

Section 7.3—Changes in State

Ch. 16: Energy and Chemical Change

Water and Its Phase Changes Wednesday, February 20, 2008 Homework: Due Thursday Page 514, #9, 19, 21, 22, 23.

White Board Practice Problems © Mr. D. Scott; CHS.

Heat in Changes of State. Review So far we’ve learned that: –Energy is the capacity to do work or cause a temperature change. –Heat is the movement of.

 MOLAR HEAT: it is the enthalpy changes(ΔH) for 1 mole of substance to change a state.  Molar Heat of Fusion (ΔH fus ): the amount of heat absorbed.

Aim: How to measure energy absorbed during a phase change

Figure 16.44: Behavior of a liquid in a closed container.

Figure 16.44: Behavior of a liquid in a closed container.

Chapter 11 (Practice Test)

Calculations in Chapter 10. Molar Enthalpy of Fusion Used when melting or freezing = ___energy ____ mol of substance Can be arranged to find any of the.

How many joules are needed to change 120.g of

Heating and Cooling Curve. Heating Curve Is a graph of heat added versus temperature Is useful in describing the change in temperature and the amount.

Heating and Cooling Curve Definitions: Specific Heat: Amount of energy required to raise the temperature of 1 gram of a substance by 1⁰ Celsius Enthalpy.

Practice Energy Calculation Quiz. How much energy does it take to convert 722 grams of ice at  211  C to steam at 675  C? (Be sure to draw and label.

For this heating curve, energy was added at a constant rate. This is obvious in regions where the temperature steadily increases (AB ; CD ; EF). In these.

Energy Requirements for changing state: In ice the water molecules are held together by strong intermolecular forces. The energy required to melt 1 gram.

Phase Changes. solidliquidgas melting freezing vaporizing condensing sublimination endothermic exothermic.

Temperature ( o C) Heat (J) Solid Liquid Gas Heat = mass x ΔT x C l Heat = mass x H Fusion Heat = mass x H Vaporization s ↔ l l ↔ g H Vaporization H Fusion.

$$$ Review $$$ Thermochemistry. Gives off heat (emits) exothermic.

Calculating Heat. Specific Heat Amount of heat energy needed to raise the temp of 1 ml of a substance 1°C For water the specific heat is 4.19 J/g °C,

ENERGY CALCULATION PRACTICE UNIT 3. HOW MUCH ENERGY IS REQUIRED TO HEAT 200 GRAMS OF WATER FROM 25˚C TO 125˚C? HOW MUCH ENERGY IS RELEASED WHEN COOLING.

Chapter 13 Solids and Liquids.

NOTES: 17.3 – Heat in Changes of State. RECALL… ● when a substance changes state (i.e. melts, freezes, vaporizes, condenses) it does not change temperature.

Heat: Phase Change. 'change of phase' 'change of state'. The term 'change of phase' means the same thing as the term 'change of state'. o These changes.

10.4  Phase – any part of a system with uniform composition and properties.  Condensation – gas changes to a liquid  Molecules of liquid can evaporate.

Heating & Cooling Curves A STEP BY STEP PRACTICE PROBLEM © Mr. D. Scott; CHS.

Heat & Changes of State. Changes of State Solid to liquid Solid to liquid Liquid to solid Liquid to solid Liquid to gas Liquid to gas Gas to liquid Gas.

1  H = H final - H initial If H final > H initial then  H is positive Process is ENDOTHERMIC If H final > H initial then  H is positive Process is ENDOTHERMIC.

1Mullis Heating Curve at Constant Pressure Curve is flat during phase changes. Area A: Temperature remains constant until all the solid has become liquid.

Molar Enthalpy of Vaporization

Phase Changes and Thermochemistry

Heat in Changes of State. Energy Changes Accompanying Phase Changes Solid Liquid Gas Melting Freezing Deposition CondensationVaporization Sublimation.

Thermochemistry Energy in State Changes. Copyright © Pearson Education, Inc., or its affiliates. All Rights Reserved. Heats of Fusion and Solidification.

Changes of State Objectives:

Kinetic and Potential Energy on the Nanoscale. Kinetic Energy on the Nanoscale thermal energy Baseball Looking at a tiny piece within the baseball.

Enthalpy (ΔH). Calorimetry the measurement of heat flow in/out of a system performed in a calorimeter the heat released by the system is equal to the.

Heating Curves. Energy and Phase Change When adding heat to a solid, energy added increases the temperature and entropy until the melting point is reached.

Section 7.3—Changes in State What’s happening when a frozen ice pack melts?

Phase Changes in Water AIM: How does the Atmosphere store energy?

Thermochemistry Enthalpy: change in heat. Energy and Change of State You do not have to write this When energy is added to a solid substance, its temperature.

Segments A, C, and E represent energy transfer from the heating source (heat) resulting in the increase in temperature of each particular state. Segments.

Phase Change Problems.

Thermochemical Calculations

Heat in Phase Changes. Review So far we’ve learned that: –Energy is the capacity to do work or cause a temperature change. –Heat is the movement of energy.

Energy and Phase Changes. Energy Requirements for State Changes To change the state of matter, energy must be added or removed.

3.3 Phase Changes What are six common phase changes?

B. Heating Curves Melting - PE  Solid - KE  Liquid - KE  Boiling - PE  Gas - KE 

Phase Changes.  A PHASE CHANGE is a reversible physical change that occurs when a substance changes from one state of matter to another  The temperature.

Calculating Heat During Change of Phase Heat Added (J)

Chapter 11 Thermochemistry- Heat and Chemical Change 11.3 Heat and changes of state.

What is the difference between energy, heat and temperature?

Energy in Phase Changes. System vs. Surroundings The system is the part of the universe that interests us, i.e. the reactants and products in a chemical.

Warm up In an exothermic reaction, the products have (more/less/same) energy as the reactants? 2.Positive enthalpy is a _______ reaction 3.Adding.

Aim: How to measure energy absorbed during a phase change DO NOW: 1. A g piece of iron absorbs joules of heat energy, and its temperature.

11.3 Heat in Changes of State. Warm up Is it exo- or endothermic???? -negative ΔH -positive ΔH -Heat as a reactant -Heat as a product -Combustion of.

© 2009, Prentice-Hall, Inc. Thermochemistry (Ch. 5 & Sections 8.8 & 11.4 ) Lecture 1 - Intro.

REVIEW 1.Write a formula for the freezing of water. 2.Write a formula for the boiling of water. 3.Write a formula for the condensing of water. 4.Write.

Types of energy POTENTIAL ENERGY : STORED ENERGY. The energy inside the substance. KINETIC ENERGY : Associated with motion. Average KE = TEMPERATURE.

1 OBJECTIVES: –Classify, by type, the heat changes that occur during melting, freezing, boiling, and condensing. –Calculate heat changes that occur during.

Phase Changes, Heat of Fusion, and Heat of Vaporization

Heating & Cooling Curves

Changes of State units: J/g Heat of Vaporization

Heating curves and DH temperature added energy.

Heating and Cooling Curves

Phase Changes Notes.

Presentation transcript:

Heating curves and  H temperature added energy

Heating curves and  H temperature added energy solidliquidgas

Heating curves and  H temperature added energy melting/ freezing pt solidliquidgas

Heating curves and  H temperature added energy melting/ freezing pt boiling/ cond. pt solidliquidgas

Heating curves and  H temperature added energy melting/ freezing pt boiling/ cond. pt solidliquidgas melting/freezing occurring here boiling/condensing occurring here

How is the total enthalpy change (  H) calculated for a substance whose temperature change includes a change in state?

temperature added energy  t of solid absorbing energy

temperature added energy  = m x C solid x  t

temperature added energy  = m x C solid x  t the energy absorbed as a solid melts becomes potential energy, so no  t

temperature added energy  H =  H fus x # mols  = m x C solid x  t

temperature added energy  H =  H fus x # mols  t of liquid absorbing energy  = m x C solid x  t

temperature added energy  H =  H fus x # mols  = m x C liquid x  t  = m x C solid x  t

temperature added energy  H =  H fus x # mols the energy absorbed as a liquid boils becomes potential energy, so no  t  = m x C liquid x  t  = m x C solid x  t

temperature added energy  H =  H fus x # mols  H =  H vap x # mols  = m x C liquid x  t  = m x C solid x  t

temperature added energy  H =  H fus x # mols  H =  H vap x # mols  t of gas absorbing energy  = m x C liquid x  t  = m x C solid x  t

temperature added energy  H =  H fus x # mols  H =  H vap x # mols  = m x C gas x  t  = m x C liquid x  t  = m x C solid x  t

temperature added energy  H =  H fus x # mols  H =  H vap x # mols  = m x C gas x  t  = m x C liquid x  t  = m x C solid x  t

temperature added energy  H =  H fus x # mols  H =  H vap x # mols  = m x C gas x  t  = m x C liquid x  t  = m x C solid x  t The  H of any substance being heated will be the sum of the  H of any  t occurring plus  H of any phase change occurring

temperature added energy  =  H fus x # mols  =  H vap x # mols  = m x C gas x  t  = m x C liquid x  t  = m x C solid x  t The  H of any substance being heated will be the sum of the  H of any  t occurring plus  H of any phase change occurring

temperature added energy  H =  H fus x # mols  H =  H vap x # mols  = m x C gas x  t  = m x C liquid x  t  = m x C solid x  t EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C?

temperature added energy -20 o C 0 o C 50 o C EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C?

temperature added energy EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C? -20 o C 0 o C 50 o C use the following values: C ice = 2.1 J/g o c,  H fus H 2 O = 6.01 kJ/mol, C H 2 O liq = J/g o C

temperature added energy -20 o C 0 o C 50 o C  H  =  H fus x # mols   = m x C liquid x  t   = m x C solid x  t EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C? use the following values: C ice = 2.1 J/g o c,  H fus H 2 O = 6.01 kJ/mol, C H 2 O liq = J/g o C

temperature added energy -20 o C 0 o C 50 o C  H  =  H fus x # mols   = 10g x 2.1 J/g o C x 20 o C EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C? use the following values: C ice = 2.1 J/g o c,  H fus H 2 O = 6.01 kJ/mol, C H 2 O liq = J/g o C   = m x C liquid x  t

temperature added energy -20 o C 0 o C 50 o C  H  =10 g x 1mol/18g x 6.01kJ/mol   = 10g x 2.1 J/g o C x 20 o C  H 2 =10 g x 1mol/18g x 6.01 kJ/mol EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C? use the following values: C ice = 2.1 J/g o c,  H fus H 2 O = 6.01 kJ/mol, C H 2 O liq = J/g o C   = m x C liquid x  t

temperature added energy -20 o C 0 o C 50 o C   = 10g x J/g o C x 50 o C   = 10g x 2.1 J/g o C x 20 o C  H 2 =10 g x 1mol/18g x 6.01 kJ/mol EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C? use the following values: C ice = 2.1 J/g o c,  H fus H 2 O = 6.01 kJ/mol, C H 2 O liq = J/g o C

temperature added energy -20 o C 0 o C 50 o C   = 10g x J/g o C x 50 o C   = 10g x 2.1 J/g o C x 20 o C  H 2 =10 g x 1mol/18g x 6.01 kJ/mol EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C? use the following values: C ice = 2.1 J/g o c,  H fus H 2 O = 6.01 kJ/mol, C H 2 O liq = J/g o C total  H =   +  H 2 +  

temperature added energy -20 o C 0 o C 50 o C   = 10g x 2.1 J/g o C x 20 o C  H 2 =10 g x 1mol/18g x 6.01 kJ/mol EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C? use the following values: C ice = 2.1 J/g o c,  H fus H 2 O = 6.01 kJ/mol, C H 2 O liq = J/g o C total  H =   +  H 2 +   = 420 J J J   = 10g x J/g o C x 50 o C

temperature added energy -20 o C 0 o C 50 o C   = 10g x 2.1 J/g o C x 20 o C  H 2 =10 g x 1mol/18g x 6.01 kJ/mol EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C? use the following values: C ice = 2.1 J/g o c,  H fus H 2 O = 6.01 kJ/mol, C H 2 O liq = J/g o C total  H =   +  H 2 +   5853 J = 420 J J J   = 10g x J/g o C x 50 o C

temperature added energy -20 o C 0 o C 50 o C   = 10g x 2.1 J/g o C x 20 o C  H 2 =10 g x 1mol/18g x 6.01 kJ/mol EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C? It takes 5853 joules to heat up 10 grams of water from -20 o C to +50 o C.   = 10g x J/g o C x 50 o C

temperature added energy -20 o C 0 o C 50 o C   = 10g x 2.1 J/g o C x 20 o C  H 2 =10 g x 1mol/18g x 6.01 kJ/mol EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C? It takes 5853 joules to heat up 10 grams of water from -20 o C to +50 o C.   = 10g x J/g o C x 50 o C

temperature added energy -20 o C 0 o C 50 o C EXAMPLE : What is  H for 10 g water with a total  t from -20 o C to +50 o C? It takes 5853 joules to heat up 10 grams of water from -20 o C to +50 o C J