Matter and Energy

1. Matter and Energy

2. Matter • Matter is anything that has mass and volume • Two forms of matter • Pure Substances • Mixtures

3. Pure substances • Uniform composition • The same throughout the sample • Two Types • Elements • Compounds

4. Elements • Simplest form of matter • Cannot breakdown • Smallest part called atom • Represented using a capital letter or capital letter and lower case letter

5. compound • Two or more elements chemically joined in a specific ratio • Can be broken down • Decomposed • Properties of the compound are different than the elements that make it up

6. mixture • Two or more substances physically joined in any ratio • Keep the properties of the components of the mixture • Two types • Heterogeneous • Homogeneous

7. Heterogeneous Homogeneous Visible difference between components (parts) No visible differences between components (parts) Called a solution Represented using (aq) aqueous

8. Properties of matter • Physical Properties • Properties that can be observed without changing the substance • Chemical Properties • Properties that show how a substance reacts (changes)

9. Energy • Energy is the driving force behind change • Cannot be created or destroyed • Does change its form • Sound • Chemical • Radiant (light) • Electrical • Atomic (nuclear) • Mechanical • Thermal (heat)

10. Two types of energy • Kinetic • Energy of motion • Potential • Stored energy

11. Measurements involving energy • Temperature • Average kinetic energy of particles • Measured using a thermometer (unit: degrees) • Fahrenheit • Celsius • Kelvin • To convert • °F to °C -- use °C = 5/9( °F - 32) • °C to ° F -- use °F = 9/5°C + 32 • °C to K -- use K = °C + 273 • K to °C– use K = °C + 273

12. Measurements involving energy • Calorimetry • Measures the actual energy (q) in a system • Related to mass (m), specific heat capacity (C) and temperature change (∆T) • Measured using a calorimeter (unit: joules) • To calculate energy use • q = m C ∆T • q = m Hfusion • q = m Hvaporization

13. Cwater = 4.18J/g °C Hfus= 334J/g Hvap = 2260J/g • How many joules are required to heat 40g water at 30°C to 70°C? q = m C ∆T q = 40g x 4.18J/g°C x 40°C q = 6688J • 5000J were added to 30g water at 25°C. What is the new temperature? q = m C ∆T 5000J = 30g x 4.18J/g°C x ∆T 5000 = 125.4 x ∆T ∆T = 39.9 ~ 40 T new= 25 + 40 T new= 65°C • How many joules are needed to melt 100g ice at 0°C q = m Hfus q = 100g x 334J/g q = 33400J

14. Phases of Matter • Solids • Liquids • Gases

15. Solids • Matter that has specific shape and specific volume • Atoms closely packed together • Cannot be compressed

16. Liquids • Matter that has a specific volume but takes the shape of the container • Atoms are close but have some space between them • Cannot be compressed • Can be poured

17. Gases • Matter that takes the shape and volume of the container • Atoms have free space between them • Compressible • Can be poured

18. Phase Changes If energy is added… • Melting • Solid to liquid • Boiling • Liquid to gas • Sublimation • Solid to gas

19. Phase Changes If energy is removed… • Freezing • Liquid to solid • Condensing • Gas to liquid • Deposition • Gas to solid

20. Phase Diagram Heating Curve for a Substance boiling gas melting liquid solid

21. Phase Diagram Heating Curve for a Substance potential kinetic potential kinetic kinetic

22. condensing freezing