HEAT & THERMAL ENERGY CH. 16. State indicator 17. Demonstrate that thermal energy can be transferred...
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Transcript of HEAT & THERMAL ENERGY CH. 16. State indicator 17. Demonstrate that thermal energy can be transferred...
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HEAT & THERMAL ENERGY
CH. 16
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State indicator
17. Demonstrate that thermal energy can be transferred by conduction, convection or radiation (e.g., through materials by the collision of particles, moving air masses or across empty space by forms of electromagnetic radiation).
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Heat flows spontaneously from hot objects to cold objects
Heat is also the transfer of thermal energy.
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What is Temperature?
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Temperature is related to the average kinetic energy of an objects particles due to their random motion through space.
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Temperature
The reference point on the Kelvin scale for temperature is absolute zero.
0 = -273o C Absolute zero – a temperature of 0°K. Room temp. would be 293o K
The purpose for this is when we study gases, which have very low freezing points.
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Thermal energy depends on mass, temperature and phase of an object.
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Thermal expansion occurs because particles of matter tend to move farther apart as temperature increases.
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Gas expands more than liquids and solids
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Specific Heat
The lower a material’s specific heat is, the more its temperature will rise when energy is applied.
Heat needed to raise the temp. of a 1g of an object 1° Celcius.
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Specific Heat
Unique to every material The lower an object’s
specific heat, the more the temp. increases when heat is absorbed.
Water has a large specific heat. Needs a lot of heat to change its temp
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Heat
Heat is measured in Joules or calories. One calorie is the energy the required to
raise the temp. of 1g of water by 1oC. One calorie is equal to 1.184 J The unit for specific heat is J/g oC
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Q = m c ΔT Q= heatM= massC= specific heat (unique for
the substance)ΔT = change in temperature
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A calorimeter uses the principal that heat flows from hotter to colder objects until they both reach the same temperature.
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Heat and Thermodynamics
Conduction in gases is slower than liquids & solids because the particles collide less often
Transfer of heat through direct contact is CONDUCTION
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Thermal Conductors Material
that conducts thermal energy well. Examples: copper & aluminum pots & pans; wood vs. tile flooring
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Thermal Insulators Material that conducts thermal energy poorly. Examples: air in a double pane window, wood,
fiberglass, fat
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Convection
Transfer of heat through moving particles in fluids (liquids & gases).
Convection currents are important in many natural cycles.
Convection Current occurs when a fluid circulates in a loop as it heats and cools. Example: oven
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Radiation
Examples: Heat from the sun, heat lamps used in restaurants
light colored object Reflect heat dark colored object Absorb heat
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The first law of thermodynamics
ENERGY is CONSERVED!
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The 2nd Law of thermodynamics
Heat can only flow from colder to hotter if work is done on the system.
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The 3rd Law of Thermodynamics
Absolute Zero cannot be reached People are trying! Current record is down to about 90
picokelvin! That’s 9.0 x 10^(-11)
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Temperature and Conductivity
http://www.youtube.com/watch?v=yXT012us9ng
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2 types of engines
Internal combustion External combustion A heat engine is any device that converts
heat into work. Thermal energy that is not
converted into work is called waste heat. Waste heat is lost to the environment.
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Internal combustion engine
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External combustion engine
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Most heating systems are convection to distribute thermal energy
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Heat pumps must do work on a refrigerant in order to reverse the flow of thermal energy
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Alternate home heating is part of our energy future!