High-TC Superconductivity

Introduction

The discovery of high-temperature superconductivity in 1987 has made it possible to study the change in conductivity at temperatures above the boiling point of liquid nitrogen (77 ^○K). Many ‘normal’ metals (e.g. Pb, Hg) undergo a phase transition at a few ^○K to a state where the conduction of electricity is effected by correlated electrons (Cooper pairs) and is almost resistance-free. High-temperature superconductivity on the other hand occurs in complicated compounds, e.g., yttrium barium copper oxide that usually exhibit conduction in two-dimensional planes of the crystal. The conduction mechanisms are not well known yet, but it is clear that the usual theory of superconductivity (BCS model) is not applicable. Also the change in conductivity is not as drastic as in a conventional superconductor.

In this experiment we investigate a semiconductor chip made of Y₁Ba₂Cu₃O₇ that contains a pair of Josephson Junctions (JJ). The combination of two JJ in parallel is called a SQUID - a superconducting quantum interference device. It permits to display quantum phenomena on a macroscopic scale, which is very remarkable, since usually quantum phenomena are restricted to the microscopic scale. The SQUID can also be used as a simple probe that goes into a superconducting state when T < T_c , provided that the current passed through it is not too large.

The experiment contains three parts: (i) a measurement of the current-voltage characteristic for the JJ connected in parallel as the chip is immersed in liquid nitrogen; (ii) a measurement of the resistivity of the JJ as a function of temperature; (iii) a measurement of the response of the JJ to a magnetic field induced by a coil that is imprinted on the circuit board. The latter experiment demonstrates the quantization of magnetic flux in a JJ loop.

All three experiments are relatively straightforward to perform, but the analysis of part (iii) requires a significant amount of literature survey (see ref. 1, chapter V, and the references cited there) to understand the physics.

Procedure

The equipment consists of the SQUID chip mounted on a rod with a metal shield to reduce the effects of external magnetic fields, a control box that contains circuitry to supply voltages and to amplify voltages in the microvolt range to millivolts that can be displayed on an oscilloscope. For the liquid-nitrogen bath a one-litre dewar bottle is used, and a temperature gauge is assembled using a silicon diode, a constant-current power supply and a digital voltmeter.

CAUTION: The handling of liquid nitrogen requires special care: safety glasses and gloves are required for filling and carrying the dewar flask, immersion of objects into the liquid nitrogen is accompanied by boiling and spray of the fluid that will cause severe burns if it comes in contact with your skin or eyes! Wear glasses and appropriate clothing and make sure not to trip over the dewar flask while experimenting!

The procedure is not described in detail here, use the appropriate sections of ref. 1.

Part 1

The current-voltage characteristic is taken in order to demonstrate superconductivity and to understand that the superconducting effect is possible only up to a certain critical value of the current. The control box is described on p. 14 of ref.1. Perform the battery check and turn the deviceoff when not in use (so as not to deplete the two 9V batteries at a fast rate). Connect the oscilloscope that is operated in X-Y mode. The control box has to be operated in V-I mode for parts 1 and 2 of the laboratory.

The following remarks are important to understand the results displayed on the oscilloscope. An oscilloscope displays voltages, and contains amplifiers for both X and Y (we are not using the timebase at all for these measurements) to boost signals from the millivolt range to create deflections of the electron beam in the tube. To display a current one needs to pass the latter through a resistor to measure the voltage that arises. This resistor is part of the control box and has a value of 10 k Ω. Thus, one converts the X display (V_x in millivolts) to a current by dividing by 10 k Ω (Ohm’s law). For the Y display another conversion is required. The voltage measured across the JJ is in the microvolt range. To display it on a scope an amplifier is contained in the control box that boosts it to the millivolt range, i.e., on the Y channel we observe V_y in millivolts. The control box amplifier for the Y channel has a gain of 10,000. This value was chosen such that the resistance (in Ω) can be read off directly from the ratio V_y/V_x as observed on the scope (Ohm’s law for the JJ in the regular or superconducting regimes). When quoting values for the critical current or voltages make sure to perform a proper conversion to true values!

Follow the procedure outlined on pp. 14-16 of ref. 1 to obtain a display of the V-I characteristic on the scope (Fig. 3.3 on p. 16). Adjust the flux bias control to optimize the superconducting regime. This control regulates how much current is passed through the gold coil imprinted on the circuit board (see Fig. 3.6 on p. 20) and helps to cancel magnetic fields trapped in the SQUID while it was cooled to below-critical temperatures.

Fig. 3.5 on p. 18 explains how to read off the critical current (displayed as V_x) and the resistance in the non-superconducting regime (super-critical current). A factor-of-two correction for the resistance and the critical current comes from the fact that two JJ are connected in parallel. The critical current (magnitude) is given by dividing the horizontal width of the flat region of the V-I characteristic in addition by two, since the positive and negative current directions are displayed. The two parallel JJ are assumed to be identical (which is not quite true in practice). Try to determine the resistance in the superconducting regime by increasing the Y-magnification on the scope.

Calculate the critical current I_c and the normal resistance RN. The product of these two quantities determines a voltage that characterizes the SQUID and enters the beta parameter to be determined in part 3. Use the provided data sheet to report your values. Once you have read off the critical current and the normal resistance you can lift the SQUID carefully out of the dewar and observe on the scope how the V-I characteristic changes as the JJ warm up.

Do not touch any parts lifted out of the dewar until they have warmed to room temperature (it burns)! Wear safety glasses and gloves.