№
|
Theme
|
What is being studied
|
The student will
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Number of hours
|
Date
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Heat phenomena
|
1
|
Motion of atoms and molecules.
|
Brownian motion. Diffusion. Molecular-kinetic theory.
|
Describe experimental proofs and show examples of Molecular-Kinetic Theory.
|
1
|
|
2
|
Temperature and internal energy.
|
Temperature. Temperature scales. Internal energy.
|
Describe usage of thermal expansion in temperature measurement;
Use different temperature scales (Kelvin, Celsius);
Describe ways of changing of internal energy.
|
1
|
|
3
|
Heat transfer. Application of heat transfer.
|
Heat transfer. Conduction. Convection. Radiotion.
|
Compare different types of heat transfer;
Tell examples of heat transfer in daily life and industry;
Tell examples of adaptation of living organisms to different temperatures.
|
1
|
|
4
|
Specific heat capacity.
|
Mass of the substance. Type of the substance. Change in the temperature of the substance.
|
Determine heat lost and heat given during heat transfer;
Explain physical meaning of specific heat capacity.
|
1
|
|
5
|
Heat of combustion.
|
Heat of combustion. Formula of heat of combustion.
|
Apply formula of heat of combustion to solve problems.
|
1
|
|
6
|
Heat exchange.
|
Heat exchange. Heat balance.
|
Apply equation of heat balance to solve problems.
|
1
|
|
States of matter
|
7
|
Melting and freezing.
|
Melting. Specific latent of fusion. Freezing. Formula of freezing/ melting.
|
Use Molecular-Kinetic Theory to describe melting and freezing;
Apply formula of freezing/ melting for problem solving.
|
1
|
|
8
|
Evaporation and condensation.
|
Evaporation. Specific latent heat of evaporation. Condensation.
|
Use Molecular-Kinetic Theory to describe boiling and condensation;
|
1
|
|
9
|
Graphical analysis.
|
Temperature-time graph of melting and freezing; boiling and condensation.
|
Analyze temperature-time graph of melting and freezing;
Analyse temperature-time graph of boiling and condensation.
|
1
|
|
10
|
Humidity.
|
Humidity. Humidity and Temperature. Boiling and Air pressure.
|
Determine amount of heat during boiling;
Explain dependence of boiling point on external pressure.
|
1
|
|
Thermodynamics
|
11
|
First law of thermodynamics.
|
First law of thermodynamics.
|
Explain the first law of thermodynamics.
|
1
|
|
12
|
Heat engines.
|
Heat engines.
|
Describe transformations of energy in heat engines;
Explain working principles internal combustion engine and steam turbine.
|
1
|
|
13
|
Efficiency of heat engine.
|
Efficiency of heat engine. The formula of efficiency.
|
Determine efficiency of heat engine;
Propose methods to increase efficiency of heat engines.
|
1
|
|
14
|
Ecology and energy.
|
Fossil fuels. Biomass fuels. Nuclear fuels. Water power. Sun and wind power.
|
Estimate the effect of heat engines on ecology of environment.
|
1
|
|
Electrostatics
|
15
|
Electric charge.
|
Electric charge. Charging methods. Positive and negative effects of charging.
|
Characterize electric charge;
Explain charging by friction and induction;
Give examples of positive and negative effects of charging;
Explain charging by rubbing, induction and contact.
|
1
|
|
16
|
Conservation of electric charge. Coulomb’s law.
|
Conservation of electric charge. Interaction between charges. Coulomb’s law.
|
Explain law of conservation of charge;
Apply Coulomb’s law for problem solving.
|
1
|
|
17
|
Electric field.
|
Electric field.
|
Explain physical meaning of “electric field” and determine its dynamics characteristics;
Calculate force applied on charge by electric field;
Show electric field by using electric field lines.
|
1
|
|
18
|
Electric potential. Potential difference.
|
Potential. Potential difference.
|
Explain physical meaning of electric potential and potential difference.
|
1
|
|
19
|
Capacitance and capacitors.
|
Electric capacitance. Capacitors. Parallel plate capacitors.
|
Describe structure of capacitor and its function.
|
1
|
|
|
