Capacitance

Capacitance package

Capacitance features

  • Virtually no magnetic field-induced errors
  • Capable of mK control stability in the presence of strong magnetic fields
  • Monotonic in C versus T to nearly room temperature

Temperature reproducibility

Over a period of days, thermal cycling of capacitance sensors can provide variations in their capacitance/temperature values equivalent to several tenths of a degree at 4.2 K, 77 K, and room temperature. Over longer periods of time, variations can reach one degree or more. However, any reduced capacitance, C(T)/C(4.2 K), is generally stable to within ±0.5 K. These variations, or shifts, in the temperature response curve have no effect on the sensor's stability when operating at a given temperature and, therefore, do not impair the sensor's primary function as a control element.

Temperature stability/temperature transfer accuracy

Capacitance sensors will provide very stable control conditions for long periods of time at operating temperature, but because an operational ‘aging’ phenomenon exists, care must be taken to account for this occurrence in their use.

The variation in capacitance/temperature characteristics is likely the result of the time dependence of the dielectric constant and the dielectric loss, or "aging," that all ferroelectric dielectrics exhibit. This time dependence, which occurs as a short-term drift (minutes to hours) in capacitance/temperature value, is initiated by disturbing the sensor thermally or by changing the voltage or frequency of excitation. To compensate for this, the sensor should be stabilized for one hour after the initial cool-down to the desired operating temperature and whenever significant adjustments in control temperature are made.

After the one-hour stabilization, this short-term drift is on the order of a few tenths of a millikelvin per minute at 4.2 K and several millikelvin per minute at 305 K. The drift is always in the direction of decreasing capacitance; consequently, it corresponds to decreasing temperature below 290 K.

CS capacitance sensors are ideally suited for use as cryogenic temperature control sensors in strong magnetic fields because they exhibit virtually no magnetic field dependence. Displacement current is not affected by magnetic fields. Consequently, temperature control fluctuations are kept to a minimum when sweeping magnetic field or when changing field values under constant temperature operation.

Because small variations in the capacitance/temperature curves occur upon thermal cycling, calibrations must be transferred to the capacitor from another sensor after cooling for the best accuracy. It is recommended that temperature in zero field be measured with another temperature sensor and that the capacitance sensor be employed only as a control element.

Use a capacitance sensor in conjunction with an RTD for magnetic applications

packaging optionsCS-501GR
 

Lead extensions

Compatible temperature controllers

Capacitance measurements are available on both the Model 336 and Model 350 temperature controllers with the addition of the Model 3061 capacitance option card. Paired with a Cernox temperature sensor, this provides a highly stable and flexible temperature control solution when sweeping magnetic field across multiple temperature steps.

Model 336 temperature controller