Download presentation
Presentation is loading. Please wait.
Published byVictor Price Modified over 8 years ago
2
Total energy in molecules of a substance including a) kinetic E of moving molecules b) potential E stored in chemical bonds
3
Average kinetic energy per molecule Average speed of molecule KE = ½ m V 2 m = mass V = velocity Velocity or speed is most important 0 velocity = absolute 0….no motion of particles
4
Flow of thermal Energy from hot to cold Transfer of kinetic energy from one molecule to another http://www.gcse.com/energy/images/conduction.gif http://www.gcse.com/energy/images/conduction.gif
5
1) Energy can not be created or destroyed only converted from one form to another or transferred from one place to another 2) Heat energy flows from high temperature areas to low temperature areas only
6
No net flow of heat energy because all areas are the same temperature Heat flows from hot to cold until…. Thermal equilibrium is reached…. Then it just passes back and forth Still moving so still heat!
7
Measure their own temperature Put thermometer in water. Heat flows Molecules of alcohol speed up and expand or slow down and contract Thermal equilibrium between thermometer and water causes red line to stop moving. http://www.middleschoolchemistry.com/multimedia/chapter1/lesson3#heating_and_cooling_a_thermo meter http://www.middleschoolchemistry.com/multimedia/chapter1/lesson3#heating_and_cooling_a_thermo meter
8
Temperature is measured in… o Celsius Heat is measures in…. calories 1 calorie = the amount of heat needed to raise the temp of 1ml H 2 O by 1 o C
9
The Calories in your food are Calories, They are actually Kilocalories = the amount of heat needed to warm up 1,000 ml of H 2 O by 1 o C
10
It takes more heat energy to increase the temperature of some substances. We say those substances have a high specific heat. Water has very High specific heat Specific heat is measured in cal/ml/ o C or cal/g/ o C
11
High specific heat warms up slower AND Cools off slower http://oceanservice.noaa.gov/education/pd/oceans_weather_climate/media/specific_heat.swf http://oceanservice.noaa.gov/education/pd/oceans_weather_climate/media/specific_heat.swf More massive http://mw2.concord.org/public/part2/he at/page2.cml http://mw2.concord.org/public/part2/he at/page2.cml
12
1) Conduction – objects touch, direct heat transfer from warm object to cold object 2) Convection – heat transferred by flowing molecules 3) Radiation – electromagnetic waves = Infrared light waves heat waves, not visible
13
Metals are good conductors because their electrons are loosely held (can flow) Non-metals hold their electrons tightly so are poor conductors called… insulators
14
Good conductors at room temperature feel: cold to the touch because…. heat is leaving your hand quickly. Poor conductors don’t feel as cold because heat is leaving more slowly
15
warm, fast moving molecules rise carrying heat with them (they expand & become less dense)
16
Electromagnetic waves =light waves Not visible Heat waves
18
Lowest energy = solid a) strongest intermolecular forces b) molecules vibrate in place so definite shape and volume Medium energy = Liquid a) weaker intermolecular forces allow molecules to flow around each other so no definite shape b) still to low energy for molecules to break away completely and expand so definite volume
19
Highest energy = gas a) weakest intermolecular forces b) molecules can flow & expand c) no definite shape or volume
20
Change in amount of thermal energy cause molecules to move in different ways Higher energy = weaker intermolecular forces as molecules expand Mass does not change Density changes
21
Solid Liquid Gas low high x = Heat energy (per mole) needed to be in that phase
23
A-B Warming ice Add E, Temp B-C Melting Add E, no ∆ Temp E used to break intermolecular forces so molecules can flow
24
C-D Warming water Add E, Temp D-E vaporization Add E, no ∆ Temp E used to break intermolecular forces so molecules can expand
25
Boiling Bubbles of gas form at bottom of liquid Evaporation High energy molecules break loose from surface of fluid
26
F-E Cooling steam Remove E, Temp E – D condensing Remove E, no ∆ Temp Loss of E lets intermolecular forces reform & hold molecules together
27
D-C Cooling water Remove E, Temp C-B freezing Remove E, no ∆ Temp Loss of E strengthens intermolecular forces so molecules can only vibrate
Similar presentations
© 2025 SlidePlayer.com. Inc.
All rights reserved.