ScienceIQ.com

Look, Up in the Sky. It's A Bird. No It's A Meteorite!

Most folks probably think of swallows and the ringing of the Mission bells when the words San Juan Capistrano are heard or seen. This is a popular tradition that celebrates the return of cliff swallows as they migrate north from their winter home in Argentina to their spring and summer home in southern California. The swallows' return typically ...

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MeteoriteSky
Geology

Natural Gas - The Blue Flame

It is colorless, shapeless, and in its pure form, odorless. For many years, it was discarded as worthless. Even today, some countries (although not the United States) still get rid of it by burning it ... Continue reading

NaturalGasTheBlueFlame
Engineering

Man Versus Machine

Computers and automation are designed to help people. It sounds so simple. If you've ever tried to use a machine that looks easy but turns out to be complicated and confusing, however, you know that ... Continue reading

ManMachine
Geology

What's In A Name?

Hurricane Elena as seen from the space shuttle. Have you ever wondered how hurricanes get their names? For several hundred years many hurricanes in the West Indies were named after the particular ... Continue reading

HurricaneElena
Astronomy

The Real Lord of the Rings

Why is Saturn the only planet with bright, easily seen rings? Saturn is not the only planet in our solar system with rings. Jupiter, Neptune and Uranus all have rings. Jupiter's rings are much smaller ... Continue reading

Saturn

What Give Batteries Their Charge?

WhatGiveBatteriesTheirChargeThere is in chemistry only one function that is of fundamental importance: the ability of atoms to share electrons. In any such sharing program, there must be electron donors and electron acceptors. In a great many compounds, all the atoms involved simultaneously donate and accept electrons, and everybody is happy. But each type of atom known has its own unique atomic structure that imparts uniquely different abilities to donate or accept electrons. The extent to which an atom is indeed sharing its electrons is referred to as its 'oxidation state'. When an atom undergoes a change in which it accepts more electrons, its oxidation state is reduced, When the atom gives up more electrons it is said to have been oxidized. The movement of electrons from one location to another defines an electrical current, and the force with which the electrons move is the electrical potential, or 'voltage'.

In practice, bringing two materials having different oxidation and reduction (or 'redox') potentials into contact with each other results in a flow of electrons from one to the other. Anyone who has ever managed to bite down on a piece of aluminum foil has felt the effect of the electrical current produced when the aluminum came into contact with an amalgam filling! This principle is the basis of all electrical batteries. In a battery, the two different materials are isolated from each other in such a way that they can only come into contact through an external means such as a wire or the circuits within a battery-powered radio, flashlight, remote control, or whatever the batteries are being used to power. In small batteries such as AAA, AA, C, D, and 9V batteries, one of the materials is sealed as a thin layer between two sheets of insulating material. The resulting 'sandwich' is then rolled up around a thin layer of the second material to construct the inner portion of the battery.

The structure is made so that one material is accessible from one end of the battery, and the other material is accessible from the other end of the battery. The material that will give up electrons is thus made into the 'cathode' or 'negative' terminal of the battery. The other material forms the 'anode' or 'positive' terminal of the battery and will accept the electrons given up by the cathode. When the two terminals are connected to each other through an electrical circuit, the two materials can behave as though they were actually in contact with each other, and electrons begin to flow from the cathode to the anode. It is interesting to note that all A, C, and D size batteries produce electrons through a redox process having a potential difference of 1.5 volts. They differ only in the number of electrons they can transfer in a given time, which is the electrical current that they produce.