Presentation is loading. Please wait.

Presentation is loading. Please wait.

Calorimetry Contents: Basic Concept Example Whiteboards

Published byHarry Hicks Modified over 6 years ago

Similar presentations

Presentation on theme: "Calorimetry Contents: Basic Concept Example Whiteboards"— Presentation transcript:

1 Calorimetry Contents: Basic Concept Example Whiteboards
Bomb Calorimeters

2 Calorimetry Drop a hot piece of material into water
Heat lost by hot stuff = heat gained by cold stuff

3 Calorimetry - Example 1 - finding c
A .231 kg piece of unknown substance at 98 oC is dropped into .481 kg of water at 18 oC. The final temperature of the water is 32 oC. What is the specific heat of the substance? (neglect the calorimeter cup, and assume no heat is lost to the surroundings) (cwater = 4186 JoC-1kg-1) Heat lost = Heat gained m1c1T1 = m2c2T2 (.231)c(98-32) = (.481 kg)(4186)(32-18) c = = 1800 JoC-1kg-1

4 Calorimetry - find c or m
1 | 2

5 112 kg of a mystery substance at 85. 45 oC is dropped into
.112 kg of a mystery substance at oC is dropped into .873 kg of water at oC in an insulated Styrofoam container. The water and substance come to equilibrium at oC. What is the c of the substance? (cwater = 4186 JoC-1kg-1) Heat lost = Heat gained m1c1T1 = m2c2T2 (.112)c( ) = (.873 kg)(4186)( ) c = 2650 JoC-1kg-1 2650 JoC-1kg-1

6 m(2174)(68.1-25.2) = (.625)(4186)(25.2-21.1) + (.257)(900.)(25.2-21.1)
A chunk of Mippsalipsium at 68.1 oC is dropped into .625 kg of water at 21.1 oC in a .257 kg Aluminum calorimeter. The water, Aluminum, and Mippsalipsium come to equilibrium at 25.2 oC. What is the mass of the Mippsalipsium? (cwater = 4186 JoC-1kg-1, cAl = 900. JoC-1kg-1, cMi = 2174 JoC-1kg-1) Heat lost = Heat gained m1c1T1 = m2c2T2 + m3c3T3 m(2174)( ) = (.625)(4186)( ) + (.257)(900.)( ) m = .125 kg .125 kg

7 (explain how to set up equation)
Calorimetry - Example 2 - Finding T A .250 kg piece of iron at 95.0 oC is dropped into .512 kg of water at 18.0 oC. What is the final equilibrium temperature? (neglect the calorimeter cup, and assume no heat is lost to the surroundings) (cwater = 4186 JoC-1kg-1,cFe = 450. JoC-1kg-1) Heat lost = Heat gained m1c1T1 = m2c2T2 (.250)(450)(95-T) = (.512 kg)(4186)(T-18) (explain how to set up equation) (show how to do math) T = oC = 21.8 oC

8 Calorimetry - find T 1 | 2

9 52 grams of glass at 91. 1 oC is dropped into 154 g of water at 25
52 grams of glass at 91.1 oC is dropped into 154 g of water at 25.1 oC in an insulated Styrofoam container. What will be the final equilibrium temperature if no heat is lost to the surroundings? (cwater = 4186 JoC-1kg-1, cglass = 840 JoC-1kg-1) Heat lost = Heat gained m1c1T1 = m2c2T2 (.052)(840)(91.1-T) = (.154 kg)(4186)(T-25.1) T = 29 oC 29 oC

10 (.127)(390)(99.5-T) = (.325)(4186)(T-23.6) + (.562)(840)(T-23.6)
127 grams of copper at 99.5 oC is dropped into 325 g of water at 23.6 oC in a 562 g glass beaker. What will be the final equilibrium temperature if no heat is lost to the surroundings? (cwater = 4186 JoC-1kg-1, cglass = 840 JoC-1kg-1, cCu = 390 JoC-1kg-1) Heat lost = Heat gained m1c1T1 = m2c2T2 + m3c3T3 (.127)(390)(99.5-T) = (.325)(4186)(T-23.6) + (.562)(840)(T-23.6) T = 25.6 oC 25.6 oC

11 Bomb Calorimeters The Bomb The Bomb with water jacket
The general procedure is to: accurately measure a small amount of ester into the combustion capsule, attach a weighed piece of iron fuse wire, seal the sample in the bomb, flush the bomb with O2 and pressurize to 30 atm, place the bomb into L water at 24°C record the water temperature at 30-second intervals for 5 minutes, ignite the sample by passing electric current through the fuse, record the water temperature at 30-second intervals for at least 20 minutes. Finally, measure how much of the fuse wire was consumed (by mass difference), and whether there was any soot produced. The Bomb The Bomb with water jacket Candy bar/O2/electric ignition/temperature rise

12 Bomb Calorimetry 1

13 Heat released = m1c1T1 + m2c2T2 Heat = 136856.4523 J = 137 kJ
3.215 g of a candy bar is placed in a kg bomb calorimeter, surrounded by kg of water. The entire apparatus is happily at oC before detonation, and the temperature rises to oC after. Ignore the heat retained by the combustion products. A) What is the energy released to the calorimeter and water in kilojoules? (cwater = 4186 JoC-1kg-1, cAl = 900. JoC-1kg-1) B) What is the caloric content in Kilocalories (C) if the entire candy bar has a mass of 35 grams. 1 cal = 4.18 J Heat released = m1c1T1 + m2c2T2 Heat = (3.687)(900.)( ) + (2.150)(4186)( ) Heat = J = 137 kJ Total energy = *35/4.18/3.215 = 356 kc = 356 C 134 kJ, 348 C

Download ppt "Calorimetry Contents: Basic Concept Example Whiteboards"

Similar presentations

HEAT EQUATION (in Table T)

HEAT EQUATION (in Table T)
Lecture 334/25/05. 1 st Law of Thermodynamics revisited ∆E = q + w Change in Energy content heat work.

Lecture 334/25/05. 1 st Law of Thermodynamics revisited ∆E = q + w Change in Energy content heat work.
Measuring and Using Energy Changes Section 20.2

Measuring and Using Energy Changes Section 20.2
Calorimetry.

Calorimetry.
Thermochemical Equations & Calorimetry

Thermochemical Equations & Calorimetry
Specific Heat. Names Specific Heat Capacity Specific Heat Heat Capacity.

Specific Heat. Names Specific Heat Capacity Specific Heat Heat Capacity.
THERMODYMANICS Thermodynamics is the study of the motion of heat energy as it is transferred from the system to the surrounding or from the surrounding.

THERMODYMANICS Thermodynamics is the study of the motion of heat energy as it is transferred from the system to the surrounding or from the surrounding.
17.1 Calorimetry Calorimetry is the experimental science of measuring (metry) heat (calor) transfer under controlled conditions. Almost all thermodynamic.

17.1 Calorimetry Calorimetry is the experimental science of measuring (metry) heat (calor) transfer under controlled conditions. Almost all thermodynamic.
Calorimetry C ontents: Basic Concept Example Whiteboards Bomb Calorimeters.

Calorimetry C ontents: Basic Concept Example Whiteboards Bomb Calorimeters.
Some Like it Hot and Some Sweat when the Heat is On!!! https://www.youtube.com/watch?v=vqDbMEdLiCs.

Some Like it Hot and Some Sweat when the Heat is On!!!
HeatHeat.  When two objects at different temperatures are put into contact, heat spontaneously flows from the hotter to the cooler one. If kept in contact.

HeatHeat.  When two objects at different temperatures are put into contact, heat spontaneously flows from the hotter to the cooler one. If kept in contact.
THE QUANTITY OF HEAT   The thermal energy lost or gained by objects is called heat. One calorie (cal) is the quantity of heat required to change the temperature.

THE QUANTITY OF HEAT   The thermal energy lost or gained by objects is called heat. One calorie (cal) is the quantity of heat required to change the temperature.
THERMODYMANICS Thermodynamics is the study of the motion of heat energy as it is transferred from the system to the surrounding or from the surrounding.

THERMODYMANICS Thermodynamics is the study of the motion of heat energy as it is transferred from the system to the surrounding or from the surrounding.
Thermochemistry Unit Chapter 17. Problem #1 (page 664): A 92.0 g sample of a substance, with a temperature of 55 o C, is placed in a large scale polystyrene.

Thermochemistry Unit Chapter 17. Problem #1 (page 664): A 92.0 g sample of a substance, with a temperature of 55 o C, is placed in a large scale polystyrene.
Measuring and Using Energy Changes Section 20.2. Main Idea Energy stored in chemical bonds can be converted to other forms and used to meet the needs.

Measuring and Using Energy Changes Section Main Idea Energy stored in chemical bonds can be converted to other forms and used to meet the needs.
Heat And Specific Heat. Heat Energy that is transferred from one body to another because of temperature Unit 1 calorie (cal) – heat needed to raise 1g.

Heat And Specific Heat. Heat Energy that is transferred from one body to another because of temperature Unit 1 calorie (cal) – heat needed to raise 1g.
THERMOCHEMISTRY Energy Enthalpy Specific Heat Calorimetry Phase Changes.

THERMOCHEMISTRY Energy Enthalpy Specific Heat Calorimetry Phase Changes.
Chapter 15.4 & 15.5 ENTHALPY AND CALORIMETRY.  Thermochemistry = heat changes that accompany chemical reactions and phase changes  Energy released 

Chapter 15.4 & 15.5 ENTHALPY AND CALORIMETRY.  Thermochemistry = heat changes that accompany chemical reactions and phase changes  Energy released 
Reaction Energy.

Reaction Energy.
Specific Heat & Phase Changes. Specific Heat ____________ (c) – the amount of heat required to raise the temperature of 1 g of a substance 1 °C The units.

Specific Heat & Phase Changes. Specific Heat ____________ (c) – the amount of heat required to raise the temperature of 1 g of a substance 1 °C The units.

Similar presentations

Ads by Google