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Published byNoel Horton Modified over 9 years ago
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Key Terms for Chapter 4 ViscosityBoiling point Absolute zeroCompressibility KelvinAmorphous solid SublimationCrystalline solid CondensationBrownian movement Bose-Einstein condensateDiffusion EvaporationFreezing point Melting pointCondensation point 1
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Chapter 4 PROPERTIES OF MATTER 2
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Properties of Matter Physical Properties A characteristic of the object/material (color, shape….) Physical Changes A change in a material that does not alter its identity Chemical Properties Describes how matter will react in the presence of other matter Chemical Changes Alters the identity of the material (iron rusting, burning wood) 3
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Physical Properties Property that can be observed and measured without a change in the kind of matter being observed Examples Color Density Shape Texture Hardness State or Phase Conductivity 4
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Physical Changes Does not alter the identity of the material It is a change in a physical property It remains the same kind of matter Generally easy to reverse Atoms do not rearrange Ex.: cutting a piece of paper, freezing water… 5
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Chemical Properties Describes how matter will react in the presence of other substances Ex. The tendency of iron to rust 6
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Chemical Change Alters the identity of the material and forms a new kind of matter Generally called a chemical reaction Both physical and chemical properties change Atoms are rearranged: new chemical formula Generally not a reversible reaction Energy is often produced or absorbed Ex.: burning, rusting 7
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Physical or Chemical change? Water evaporates into steam A piece of cork is cut in half A bicycle chain rusts A piece of apple rots on the ground 8
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Models Ideas that represent what might be happening No model is perfect Models can change Good models Organize ideas Describe observations Help us describe what we cannot see Predict what will happen Different types of models Solar system models DNA 9
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Matter Aristotle (and other Greek philosophers) believed that matter was continuous It could be divided infinitely without changing it This concept was generally accepted from about 500 B.C. for 1500 A.D 10
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Particle Model of Matter Matter could only be subdivided to a certain point – eventually you would not be able to divide it any more Ex. Water droplet Measure those particles in angstroms and nanometers These particles are called atoms Two or more atoms joined together forms a molecule 11
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Particle Model You can watch the diffusion of food coloring in water whether you stir it or let it sit If you let it sit long enough, the solution will spread throughout the water without stirring. How? Brownian Movement: describes the constant motion of particles in a liquid or gas 1 st introduced by a botanist Robert Brown Diffusion: mixing by this particle motion 12
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Phases of Matter 4 phases of matter Solid Liquid Gas Plasma 13
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Solid Definite shape Definite volume Usually dense: particles are packed closely together Low compressibility Particles vibrating in fixed position Low kinetic energy: strong attractive force 14
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Solid Occur in 2 basic forms: Crystalline: atoms are in a fixed, repeating structure in solid Amorphous: atom arrangement is random Ex. glass 15
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Liquid Definite volume No definite shape Low compressibility Random particle movement: Brownian Motion Particles fairly close Fairly equal kinetic energy to attractive force Viscosity: the ease with which a liquid will flow Low viscosity: liquid flows very easily (water) High viscosity: liquid does not flow easily (pancake syrup) 16
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Gas Indefinite shape Indefinite volume High compressibility Particles are far apart More kinetic energy than attractive force Brownian motion Gas pressure: from the collisions of the gas particles with the sides of the container (ex. Balloon) Heat gas = more kinetic energy 17
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Comparing Phases SolidLiquidGas VolumeDefinite Indefinite ShapeDefiniteIndefinite CompressibilityLow High 18
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Bose-Einstein Condensate Hypothetical phase of matter that exists at absolute zero Particles of the object behave as a single atom Still being studied in labs to determine it’s uses 19
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Phase Changes of Matter Temperature increases = energy increases Temperature decreases = energy decreases Adding and removing energy will result in a phase change The type of matter stays the same 20
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Phase Changes Phase changes that add energy Melting Vaporization Boiling Evaporation Sublimation 21
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Melting Change from a solid to a liquid The temperature at which melting occurs is called the melting point Water: 0 o C or 32 o F 22
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Vaporization Change from liquid to gas Boiling Occurs very quickly Depends on the air pressure above Boiling point: temperature at which substance boils Evaporation Occurs very slowly 23
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Sublimation Change from solid to gas (without becoming a liquid) Solid particles gain enough energy to escape into the atmosphere Ex. Dry ice, moth balls, snow 24
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Phase Changes Phase changes that remove energy Freezing Condensing Deposition 25
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Freezing Change from liquid to solid Liquid particles lose enough kinetic energy that the attractive forces hold the particles in place Temperature at which this occurs is freezing point Water: 0 o C or 32 o F 26
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Condensing Change from gas to liquid Temperature at which this occurs is dew point (condensation point) Ex. Dew 27
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Deposition Change from gas to solid (without becoming liquid) Ex. Frost, Ice on wings of plane 28
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Measuring Energy Temperature: Measure of average Kinetic energy Different than heat (total Kinetic energy) Celsius: 0 C Fahrenheit: 0 F Kelvin: K Absolute zero: the temperature at which all molecular motion would cease 29
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Conversions C to K – add 273 K to C – subtract 273 C to F – (C x 1.8) + 32 F to C – (F – 32)/1.8 MEMORIZE THESE CONVERSIONS 30
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Conversions Convert -182 o C to K -182 + 273 = 91 K Convert 298 K to o C 298 – 273 = 25 o C Convert 68 o F to o C 68-32 = 36/1.8 = 20 o C Convert 312 K to o F 312 – 273 = 39 o C (39 x 1.8) +32 = 102.2 o F 31
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