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A LEAF ELECTROSCOPE.

Published byDeddy Gunardi Modified over 6 years ago

Presentation on theme: "A LEAF ELECTROSCOPE."— Presentation transcript:

1 A LEAF ELECTROSCOPE

2 Insulating rubber stopper
A LEAF ELECTROSCOPE Insulating rubber stopper Knob Gold Leaves case

3 A LEAF ELECTROSCOPE The electroscope starts out neutral
This means there are an equal number of electrons and protons

4 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

5 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

6 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

7 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

8 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

9 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

10 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

11 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

12 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

13 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

14 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

15 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

16 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

17 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

18 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

19 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

20 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

21 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

22 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

23 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

24 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

25 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

26 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

27 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

28 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

29 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

30 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

31 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

32 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

33 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

34 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

35 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

36 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

37 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves. Richard J. Terwilliger April 2001 Created by

38 by Richard Terwilliger
Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves. by Richard Terwilliger

39 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

40 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

41 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

42 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

43 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

44 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

45 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

46 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

47 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

48 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

49 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

50 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

51 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

52 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves.

53 Rubber rod We will charge this electroscope net negative using a negatively charged rubber rod. As the negatively charged rod approaches the knob of the electroscope, the electrons in the knob are repelled and move down into the leaves. REPLAY

54 The knob of the electroscope lost electrons.
Rubber rod The knob of the electroscope lost electrons. Therefore the knob is now net positive and the leaves are net negative The leaves repel each other and spread apart F es The leaves gained the electrons.

55 What would happen if the rod is taken away?
Rubber rod The electroscope hasn’t lost or gained electrons so it is still neutral. What would happen if the rod is taken away? What would happen if the rod is taken away?

56 Rubber rod The electroscope hasn’t lost or gained electrons so it is still neutral. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

57 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

58 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

59 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

60 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

61 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

62 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

63 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

64 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

65 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

66 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

67 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

68 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

69 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

70 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

71 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

72 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

73 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

74 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

75 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

76 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

77 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

78 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

79 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

80 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

81 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

82 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

83 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

84 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

85 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

86 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

87 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

88 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

89 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

90 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

91 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

92 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

93 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

94 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

95 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

96 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

97 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

98 Rubber rod When the rubber rod makes contact with the knob of the electroscope some of the electrons in the rod transfer into the knob. The electrons in the rubber rod are attracted to the NET POSITIVE knob of the electroscope.

99 We will now remove the rubber rod
The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE. We will now remove the rubber rod

100 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

101 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

102 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

103 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

104 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

105 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

106 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

107 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

108 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

109 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

110 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

111 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

112 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

113 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

114 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

115 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

116 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

117 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

118 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

119 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

120 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

121 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

122 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

123 The electroscope has GAINED electrons.
Rubber rod The electroscope has GAINED electrons. The electroscope is now NET NEGATIVE.

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A LEAF ELECTROSCOPE.

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