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Flashlight Battery Energy - Light and Heat - ES - -PS - Energy

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Last updated 4 months ago
6 Nsɛmmisa
Hyɛ no nsow a efi ɔkyerɛwfo no hɔ:

Directions: Use the information provided and your knowledge of Physical Science to answer the following questions. Show all work where necessary.

Directions: Use the information provided and your knowledge of Physical Science to answer the following questions. Show all work where necessary.

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4-PS3-2
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4-PS3-2
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Flashlight Battery Energy - Light and Heat

Diagram 1.

Flashlight anatomy and electrical circuit diagram showing a battery, metal spring, switch, reflector, and bulb.

Source:

https://vamosarema.com/

Phenomenon:

Students notice that a flashlight is very bright when the batteries are fresh. After using it for a while, the light becomes dimmer, and the flashlight body feels slightly warm. Students wonder: Where does the energy from the batteries go, and how can we show that energy is conserved when it is transferred and converted?

A flashlight is a good example of how energy can be transferred and converted without being created or destroyed. Inside the flashlight, the batteries store chemical energy. When the switch is turned on, this chemical energy is transferred into electrical energy that flows through the wires. The electrical energy is then converted into two new forms: light energy from the bulb and heat energy from both the bulb and the flashlights casing.

As the batteries lose chemical energy, the flashlight becomes dimmer because there is less energy available to convert into light. However, the energy has not disappeared. Some of it becomes heat, which is why the flashlight can feel warm after being on for a while. The total amount of energy is still conserved; it has simply changed form.

Students can observe this by measuring how bright the flashlight is at different battery levels and how warm it becomes after shining for the same amount of time. These measurements help show that chemical energy is transferred and converted into light and heat energy, demonstrating energy conservation.

Table 1.

Battery Level

Brightness (lux)

Light Temperature at Bulb (C)

Flashlight Casing Temp Before (C)

Temp After (C)

Temperature Increase (C)

100%

320

32

22

28

6

50%

180

30

22

25

3

10%

70

28

22

23

1

Graph of Information - Figure 1.

Flashlight Brightness by Battery Level

Graph of Information - Figure 2.

Temperature Increase After 1 Minute by Battery Level

Asemmisa {{asɛmmisaAhyɛnsode}}
1.

Look at Table 1. How do brightness and temperature increase change as the battery level goes from 100% to 10%?

Asemmisa {{asɛmmisaAhyɛnsode}}
2.

At which battery level does the flashlight produce the most light energy?

Asemmisa {{asɛmmisaAhyɛnsode}}
3.

What pattern do you observe between battery level and temperature increase of the flashlight casing?

Asemmisa {{asɛmmisaAhyɛnsode}}
4.

Using the data, explain why the flashlight feels warmest when the batteries are at 100%.

Asemmisa {{asɛmmisaAhyɛnsode}}
5.

Which piece of evidence best shows that energy is converted into both light and heat?

Asemmisa {{asɛmmisaAhyɛnsode}}
6.

How do the brightness and temperature changes in the flashlight provide evidence that energy is conserved when chemical energy is transferred and converted into light and heat?

Claim:

Evidence:

Reasoning: