Trinity College Dublin

Above: Poulsens early Drum Telegraphone (left) followed by a later model and a drawing on his patent form.

Demonstration of the recording and playback method used by Poulsen.

By 1950 Néel had developed a theory to explain the behaviour of isolated grains of magnetic oxides such as magnetite (Fe₃O₄) or γFe₂O₃ which were the magnetic medium in recording tape but are also present in igneous rocks. He established how if the superparamagnetic fluctuations of tiny grains became blocked, the particles could acquire a stable remanent magnetization in the direction of the Earth's magnetic field. A great success of Néel's ideas of rock magnetism were the part they played in establishing that the continents we live on are continually shifting across the globe at the rate of a few centimetres a year.

The spreading ocean floor acts as a giant tape recorder, rocks in the Earth's crust cooling in the Earth's magnetic field acquire a tiny stable remanent magnetization as they become blocked, reflecting the Earth's field at the time. The field, sustained by convective motion in the deep liquid core, changes polarity chaotically, reversing maybe once in 100,000 years. At the border between two tectonic plates that are pulling apart, new crust is constantly cooling and displacing previously-cooled rock. Bands of rock of first one polarity and then the other are observed by measring the stray fields in oceanographic surveys. The hypothesis of Wegner of continental drift, long rejected by the geological community, was triumphantly vindicated and the reality of global plate tectonics was established.

 

The application of magnetic recording to computing soon followed that of audio and video recording. In 1953, a computer project team at MIT called Whirlwind introduced the magnetic core memory (left), where arrays of thousands of small doughnut-shaped magnets threaded with wires that could store and manipulate data bits into the magnets with electric current pulses. Magnetic cores remained the most reliable and inexpensive computer memories for nearly twenty years before being replaced by the semiconductor integrated circuit. Nowadays the primary random access memory (RAM) in which most of the computing is done is semiconductor-based due to its speed and higher bit density, but magnetic media provide the secondary storage on the hard disk, which stores much more information (around 10Gb in current home computers), and is cheap and nonvolatile.

 

There is a prospect that in future both semiconductor memory and the hard disk may in future be replaced by nonvolatile magnetic random access memory (MRAM, shown right) consisting of arrays of magnetic tunnel junctions.

In recent years, the areal density of information storage in magnetic recording has been doubling every two years (Moore's law), and it seems set to continue on that course until about 2004. A new rabbit has been pulled out of the sensor hat every few years to sustain the information revolution: advances in thin-film technology and the discovery of giant magnetoresistance, for example. The mechanics of accesing this information has been perfected to a large degree - the feat of control involved in scanning the read head of a hard disk above the spinning magnetic surface of the disk can be likened to flying a Boeing 747 with its nosewheel extended a few centimetres above the surface of a ploughed field.

The magnetic bits on a disc are now about 100nm² in area. Ultimately the limits on magnetic recording at room temperature will be set by the superparamagnetic behaviour of very small particles.