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Lemon battery

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A lemon cell battery is made with a lemon and two metallic electrodes of different metals such as a copper penny or a copper plating and a galvanized (zinc coated) nail. In practice, a single lemon cell is incapable of lighting a light bulb or even a flashlight bulb. It would take over 9000 lemons to power a flashlight bulb. See Calculations.

A lemon battery is a device used in experiments proposed in many science textbooks around the world.[1] It is made by inserting two different metallic objects, for example a galvanized nail and a copper coin, into a lemon. The copper coin serves as the positive electrode or cathode and the galvanized nail as the electron-producing negative electrode or anode. These two objects work as electrodes, causing an electrochemical reaction which generates a small potential difference.

Overview

The aim of this experiment is to show students how batteries work. After the battery is assembled, a multimeter can be used to check the generated voltage. In order for a more visible effect to be produced, a few lemon cells connected in series can be used to power a standard LED. Flashlight bulbs are generally not used because the lemon battery cannot produce the amount of current required to light such bulbs. Digital clocks can work well, and some toymakers offer small kits with a clock that can be powered by two potatoes or lemons.

Energy source

The energy for the battery does not come from the lemon or potato, but rather the energy comes from the chemical change in the zinc (or other metal). The zinc is oxidized inside the lemon, exchanging some of its electrons in order to reach a lower energy state, and the energy released provides the power. The lemon or potato merely provides an environment where this can happen, but they are not used up in the process.

In current practice, zinc is produced by electrowinning of zinc sulfate or pyrometallurgic reduction of zinc with carbon. The energy produced originates from this source.

Calculations

1 lemon can generate approximately 0.9 Volts. The reaction typically ranges from 0.80V - 0.98V

Volts x Amperes = Watts

1 lemon = 0.9V x 0.0003 Amps = 0.00027 Watts

Flashlight bulb = 2.4V x 0.5 Amps = 1.2 Watts, or about 5,000 lemons

Halogen bulb = 12V x 0.83 Amps = 10 Watts, or about 37,000 lemons

Red LED bulb = 1.7V x 0.0005 Amps = 0.00085 Watts, or about three lemons in series

Reactions

In a lemon battery, both oxidation and reduction occur. Consider the case of a zinc-copper battery; this battery is similar to the original "simple voltaic cells" invented by Alessandro Volta.[2] At the anode, metallic zinc is oxidised, and enters the acidic solution as Zn2+ ions:

Zn → Zn2+ + 2 e-.

At the copper cathode, hydrogen ions (solvated protons from the acidic solution) are reduced to form molecular hydrogen:

2H++ 2e- → H2.

Variations

Potato battery with copper and zinc electrodes

Potatoes,[3] apples, or any other fruit or vegetable containing acid or other electrolyte can be used, but lemons are preferred because of their higher acidity.[4] In potatoes, for instance, the electrolyte is phosphoric acid, while in lemons it is citric acid. Other non-rusty metal combinations (such as magnesium-copper) are more effective; for example, using a magnesium strip instead of zinc increases the voltage from 1.1 V with zinc to 1.6 V with magnesium. (The exact voltage varies depending on the lemons.) However, zinc and copper are usually preferred because they are reasonably safe and easy to obtain.

See also

References

  1. ^ Lemon Battery
  2. ^ Oon, Hock Leong (2007). Chemistry Expression: An Inquiry Approach. Panpac Education Pte Ltd. p. 236. ISBN 9789812711625.
  3. ^ Potato Battery
  4. ^ Food Batteries