1. 1. The Discovery of Current Electricity

2. Galvani and his frogs Luigi Galvani (1737-1798) Anatomy Prof Looking for ‘Life Force’ Found that electricity made frog legs twitch (but that wasn’t the important discovery!)

3. Galvani and his frogs

4. Showed that contact between different metals and the muscles also made the legs twitch. So were the two metals producing electricity somehow?

5. Alessandro Volta Took up Galvani’s discovery Showed that two different metals were producing the same effect as ‘electricity’

6. Alessandro Volta Wondered if static electricity and ‘metal’ electricity were really the same thing. Invented the ‘Voltaic Pile’ First battery

7. Alessandro Volta He showed that the ‘Voltaic pile’ had the same effect as static by collecting both in a ‘Leyden jar’.

8. Alessandro Volta Leyden jar Capacitors

10. J J Thomson showed that ‘cathode rays’ appeared to be negative particles that moved through metals. Now called ‘electrons’

12. Electric current: – rate of transfer of positive charge

13. Batteries push lots of charges But not very hard High current – Low Voltage Lots of charges, but low concentration Two ways to get current flowing – 2 Chemical action:

14. To flow, a current needs a ‘closed circuit’ The switch completes a path from one end of the battery to the other Current is flowing charges

15. A simple ‘closed circuit’. Path of current: Ammeter measures flow of charges (current) Ammeter measures flow of charges (current) Voltmeter measures concentration of charge (voltage) Voltmeter measures concentration of charge (voltage) Current is flowing charges Ammeter Voltmeter 2.4 volts 0.25 amps +-

16. When charges reach a thin filament they give up energy – as heat and light. How do they ‘carry’ this energy? Charges carry energy! High volts Low volts ENERGY

17. concentration of the charges The energy is carried as potential energy due to the concentration of the charges. Lower concentration lower potential energy Charges carry energy!

18. Charges have to go faster when they reach the filament... hit atoms harder … and so lose more energy. Charges carry energy! Low negative concentration (–1 V) Higher negative concentration (–12 V)

19. A little like water flowing over a waterfall Big drop (high ‘voltage’) Charges carry energy! High gravitational potential energy Low gravitational potential energy ENERGY

20. Less drop, more water Charges carry energy! Less potential energy per kilogram... but more kilograms ENERGY Less ‘volts’ but more ‘current’

23. Summary Historical introduction sets scene as a ‘human adventure’. Follows formation of ideas. Battery illustrate concepts of voltage and current well. Voltage as ‘charge concentration’ can be imagined – and is correct physics. (Sum of kq/r terms) Water flow as analogy for current has problems due to lack of ‘negative water’ and direction of flow. Water cycle as driven by Sun’s energy is a reasonable analogy for flow of energy around a circuit – compare the gravitational potential energy with the electrical potential energy. Sets scene for Power = Volts x Current = E/C x C/t

24. Electricity Basics

25. The Atom Protons Neutrons electrons