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3-omega Method

Helpful Publications:

Correspondence

Email correspondence from Jean-Yves Duquesne of Université Pierre et Marie Curie to River Wiedle (10 May 2011):

Modern lockins are able to detect coherent harmonic signal. So, in contrast to D.Cahill original setup, there is no need to synthetize a
reference triple harmonic 3w.

The temperature of the sample is regulated.

R_0 is measured accuratly: 4-wires measurement.

R_a is adjusted in order to null the output of the differential amp at the fundamental frequency w.

At every frequency, the current is measured (phase and amplitude),
thanks to the well calibrated R_i. Since the 3w signal is proportional
to I^3, it is important to monitor |I| and to keep it constant trough
the whole frequency range.

To link the measured voltage to the modulated temperature, you have to
measure accuratly the transmittance of A1+A3. For that purpose, A2 input
is shortened. The thermal transducer can replaced with a well calibrated
resistor R_r (its value is close to R_0). The frequency is swept. Input
tension on A1 is deduced from the measured current (in the calibrated
R_i) and from R_r value. Output tension (A3) is measured.

Electrical contacts to the transducer are done with conductive epoxy.
With some practice, it is possible to make small contacts, say ~300x300
µm. I avoid ultrasonic bonding since this can perforate the deposited
films.

Metal/semiconductor contacts are usually non linear, from an electrical
point of view. Then, very large harmonic signals can be produced when a
current is flowing in the thermal transducter. So it is advisable to
introduce an insulating layer between the transducer and the SC film of
interest.

Schematic of Duquesne 3w setup

Equipment & Manuals

  • SR850 Stanford Research Systems Lock-in Amplifer. SR850 Manual
  • AM502 Tektronix Differential Amplifer. Tek AM502 Manual
  • SRDS345 Stanford Research Systems Arbitrary Waveform Generator (belongs to McIntyre Lab). DS345 Manual

Apparatus Development Log

  • Instrumentation amplifiers tested: INA121, INA128, INA111. The INA128s have the least phase error of the three. (RW 05/12)
  • Phase difference drifts negatively (at high frequency) for the 121s and 128s, but drifts positively for the 111s. (RW 05/12)
  • The 'divide by two' attenuation for calibration and 1w voltage cancellation causes low-pass behavior and limits the frequency bandwidth of the circuit. Adjusting the gain between 1 and 2 doesn't seems to make a significant difference. (RW 05/12)
  • GPIB protocol must be used for talking to the lock-in (SR830/850) with LabVIEW. VISA won't work properly. (RW 05/12)

Measurement System Concerns

Measurements at low frequency

  • Finite substrate effects come into play at low frequency. This limits the range of the 'linear region' for the traditional 3\omega method. High thermal conductivity/diffusivity and small thickness of the substrate make these effects show up at higher frequency. These effects can be modeled with the Borca-Tasuic model by setting either an isothermal (Tac = 0) or adiabatic (heat transfer = 0) at the back of the substrate. We want the isothermal condition as this will be more accurate since heat can be lost through other mechanisms (contacts, wires, conduction to air, etc). For a truly isothermal condition, Tx levels off at a finite value at low frequency and Ty converges to 0. This is because the time it takes for heat to transfer across the substrate is small compared to the period of the thermal wave (the substrate can be treated as a thermal resistance layer). To achieve an isothermal condition, it is important that the substrate be heatsunk to a material of high thermal conductivity (Cu works well). Simply setting the substrate on a copper block doesn't do the trick - placing a layer of silver paint between a sanded copper block and the substrate works well. In practice, this does not create a truly isothermal boundary condition - the 'linear region' for the copper block can be seen at low frequency.
  • The lock-in amplifier has a setting for AC/DC coupling at the inputs. At low frequency (<10 Hz or so), AC coupling creates large phase and amplitude errors in the measured signal. However, any DC offset on the signal will create an additional signal at the reference frequency that needs to be filtered out (larger time constants might be required).
  • For external voltage sources, a TTL reference is required at low frequency. The SINE reference is AC coupled due to the need for an accurate zero crossing. Using SINE reference at low freq will result in phase errors.

People

The system was set up in 2011 by River Wiedle in collaboration with Mark Warner. Matt Oostman worked on the project Fall 2011→ Nico Schmidt Spring 2012 →


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