Count Alessandro Volta

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Alessandro Volta was an Italian scientist who invented the first battery that produced a steady current. The term "Volt" was named after him.

Count Alessandro Volta

Biography

Early Life and Works

Electrophorus

Alessandro Giuseppe Antonio Anastasio Volta was a man of many scientific interests. He was considered a physicist, a chemist, and a pioneer of the study of electricity and power. Volta was born in 1745 in Como, Italy and died in 1827. In 1774, he started his career as a physics professor at the Royal School in Como.

By studying electricity on the side, Volta had improved and popularized a device called the Electrophorus, which is a simple capacitive generator that produces electrostatic charge through electrostatic induction. In simple terms, this device generated static electricity. Volta continued to study and experiment with atmospheric electricity, and in 1776, he discovered and found ways to isolate methane gas in the atmosphere. in 1779, Volta was appointed the chair of physics at the University of Pavia.

Mid-Life and Inventions

In 1791, Volta's friend Luigi Galvani, a physicist who also studied electricity, had introduced to him an experiment done with frogs. Volta saw that the contact of two different metals with a particular muscle from the frog created an electrical current. Many interpretations arose as Galvani had named it as "animal electricity", where he believed that electricity could be generated in living tissue, and Volta had named it as "metallic electricity", where he believed that the frog's muscle only served as a conductor when the current flowed between the metals.

Volta came to his conclusions about "metallic electricity" through his experimentation with metals alone as he used metal disks and detected weak flow of electricity simply by placing them on his tongue. As a result, he realized that animal tissue was not a requirement for metal to create a current and that the animal tissue, as well as his tongue, served as conductors.

In the year 1800, Volta had announced his first invention, known today as the electric battery. At the time, his invention was known as and composed of a concept called the "Voltaic pile". This voltaic pile was the first electrical battery that could provide an electrical current to a circuit. This mechanism consisted of alternating disks of zinc, copper, or silver that was divided by paper, cloth, or cardboard soaked in salt water or sodium hydroxide. The name "Voltaic pile" simply described the physical aspects as it consisted of stacking pairs of alternating disks. With these alternating copper and zinc discs, Volta was able to increase the electrolyte conductivity of the device. When the top and bottom surfaces are connected by wire, an electric current flows through the voltaic pile and the wire itself. This idea formed the basis of all modern wet-cell batteries because it created a new generation of self-sustained electrical current.

Many new concepts were formed due to Volta's battery: William Nicholson and Anthony Carlisle were able to use the voltaic pile to decompose water into hydrogen and oxygen. With the study of chemistry in their field, they were able to discover the electrolysis of water. Humphry Davy discovered that chemical reaction drove electric current through a circuit containing a single voltaic cell. He was able to demonstrate carbon arc discharge which isolated five new elements currently known on the periodic table as barium, calcium, boron, strontium, and magnesium. William Hyde Wollaston discovered the similarities between electricity generated by the voltaic pile and electricity generated by friction.

The following chemical equations represent the chemical reactions in the voltaic cell:

Zinc:
Zn Zn2+ + 2e
Sulfuric acid:
2H+ + 2e H2

Positively charged hydrogen ions capture electrons from copper and makes hydrogen gas, H2. This would cause the zinc to become negative and the copper to be positive. Copper does not react and it only serves as an electrode for the electric current.

Scientific Contribution

Volta's Law of Capacitance

Although it was Wald Georg von Kleist who discovered the idea of Capacitance, Volta had already established certain ideas related to capacitance. As he studied both electric potential and charge, he realized that for any given object, these two variables changed proportionally.

Voltage (named after Volta) is the term used now to describe the amount of electrical force necessary to drive an electric current between two points. Voltage can be measured in electric potential energy per unit charge, or joules per coulomb. Volta's law of capacitance is ultimately the fundamental concepts of voltage.

Potential Difference

It is also very important to understand the difference between voltage and volts in this class: Voltage is a term that describes the electric potential concept, while volts is the unit (joules per coulomb) measurement of voltage.

To calculate the potential difference, we define an equation to be : [math]\displaystyle{ \Delta V }[/math] = -[math]\displaystyle{ \vec{E} }[/math][math]\displaystyle{ \Delta \vec{x} }[/math]

[math]\displaystyle{ \Delta V }[/math] is the potential difference

[math]\displaystyle{ \vec{E} }[/math] is the electric field

[math]\displaystyle{ \Delta \vec{x} }[/math] is the path where we want to measure the potential difference

Note that there is a dot product, and this means that we are looking for components of the electric field solely parallel to our path. There is also a negative sign in this equation; this signifies that the sign of voltage is opposite to the direction that the electric field follows a path. If the electric field follows the path in the same direction, then [math]\displaystyle{ \Delta V }[/math] is negative, and if the electric field follows the path in the opposite direction, [math]\displaystyle{ \Delta V }[/math] is positive.

Electromotive Force

Because Volta invented the first battery, he studied the electromotive force of such battery. Because voltage and volts are both named after him, the concept of EMF is a term named after what he had studied. EMF stands for electromotive force and this is what makes the electrons move from atom to atom; this also represents the source voltage of a circuit. Voltage is a more general term and can be applied to the voltage drop between different points along a circuit.

The following diagram represents how voltage and emf can be applied to other concepts in physics. Alessandro Volta has made an enormous impact in our fundamental understanding of physics, and specifically the electric aspect of science.


Application of Voltage

Putting voltage into perspective: The following examples are just some common objects we encounter with a certain amount of voltage that is necessary for us to be aware of.

Single-cell non-rechargeable batteries (AAA, AA, C, D): 1.5 V

Single-cell rechargeable batteries: 1.2 V

A car’s electrical system: 12 V

Commercial truck: 24 V

Household wall sockets (North America): 120 V

Subway system “third rail”: 600-750 V

Examples

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Middling

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Further reading

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References

External links

http://www.britannica.com/biography/Alessandro-Volta

http://inventors.about.com/od/utstartinventors/a/Alessandro_Volta.htm

http://www.corrosion-doctors.org/Biographies/VoltaBio.htm

http://www.daviddarling.info/encyclopedia/E/electrophorus.html

http://enlightenme.com/voltage/