# Difference between revisions of "Josephson junction"

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device, | device, | ||

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− | V=\frac{d\phi}{dt}. | + | V = \frac{d\phi}{dt}. |

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It follows from quantum theory [Feynman, 1970] that the current | It follows from quantum theory [Feynman, 1970] that the current |

## Latest revision as of 16:43, 23 August 2009

Josephson received the 1973 Nobel Prize in Physics for discovery of the Josephson effect, which occurs in two superconducting layers separated by an insulating oxide. Under certain conditions current can pass through the insulator through tunneling of Cooper pairs of electrons. The effect has been used to design superconducting quantum interference devices (SQUID) because switching is very fast, in the order of picoseconds. Tunneling in the Josephson junctions is very sensitive to magnetic fields and can therefore be used to measure extremely small magnetic fields with thresholds as low as Tesla. Josephson junctions are also used for other precision measurements. The standard volt is now defined as the voltage required to produce a frequency of 483,597.9 GHz in a Josephson junction oscillator.

A schematic diagram of a circuit with a Josephson junction is shown below.

The quantum effects can be modeled by the Schrodinger equation, but it turns out that the circuit can also be modeled as a system with lumped parameters. Let be the flux that is the integral of the voltage across the device,

It follows from quantum theory [Feynman, 1970] that the current through the device is a function of the flux :

where is a device parameter, and the Josephson parameter is given by

where Coluombs is the charge of an electron and is Planck's constant.

The circuit in the figure has two storage elements: the capacitor and the Josephson junction. We choose the states as the voltage across the capacitor and the flux of the Josephson junction. Let , and be the currents through the resistor, the capacitor and the Josephson junction. We have

and a current balance gives

which can be rewritten as

Combining this equation with equation for gives the following state equation for the circuit

Notice that apart from parameter values, this equation is identical to the equation for the inverted pendulum.