Operation, General description of the crystal measurement, Operation -1 – INFICON RQCM - Quartz Crystal Microbalance Research System User Manual

RQCM – RESEARCH QUARTZ CRYSTAL MICROBALANCE

OPERATION

3-1

3 OPERATION

The heart of the RQCM is the crystal measurement methodology. It is important that the user

understand its operation to ensure proper setup and application.

3.1 GENERAL DESCRIPTION OF THE CRYSTAL MEASUREMENT

The INFICON Phase Lock Oscillator (used on the Crystal Measurement Card) was developed

specifically to support the use of the quartz crystal microbalance in the measurement of lossy

films and in liquid applications. In addition to accurately tracking the frequency of heavily

damped crystals, the RQCM also tracks the crystal’s resistance. This provides additional

information in the study of lossy films and/or viscous solutions.
The PLO utilizes an internal oscillator referred to as a Voltage Controlled Oscillator (VCO) to

drive the crystal. The crystal current is monitored and the frequency of the oscillator is adjusted

until there is zero phase between the crystal voltage and current. Assuming that the crystal’s

electrode capacitance has been effectively cancelled, this point of zero phase between the crystal

current and voltage is the exact series resonant point of the crystal. The magnitude of the current

at this point is directly proportional to the crystal’s conductance. This current is monitored by the

RQCM and displayed as crystal resistance. The PLO contains a phase detector that continuously

monitors the phase difference between the crystal’s current and voltage. At frequencies below

the crystal’s resonant frequency the current leads the voltage and the phase goes to 90 degrees as

the frequency separation continues to increase, see Figure 19. Above the resonant point the

current lags the voltage and the phase go to minus 90 degrees. As the frequency increases

through the resonant frequency, the phase goes from plus 90 through 0 to minus 90. It is

interesting to note that the phase angle is 45 degrees when the VCO frequency is one half of the

crystal’s bandwidth above or below the crystal’s resonant frequency.
The output of the phase detector is fed into an integrator. The integrator accumulates the phase

error such that any positive phase error causes the integrator output to climb; a negative phase

causes the integrator output to fall. With zero phase error the Integrator output holds steady.
The integrator output is connected to the VCO. Thus, if the VCO frequency is initially below the

crystal resonant frequency, the phase will be positive, producing a positive output at the phase

detector. This causes the Integrator output to climb, which causes the VCO frequency to

increase. When the VCO frequency matches the resonant frequency of the crystal the phase will

decrease to zero, the phase detector output will go to zero, the Integrator output will hold steady

and the VCO frequency will be “locked” to the crystal’s resonant frequency.
If the crystal’s resonant frequency moves up or down, a phase difference between the crystal

voltage and current will develop, producing a phase detector output. The non-zero phase detector

output will drive the Integrator output up or down until the phase is zero once again, thus keeping

the VCO frequency locked to the crystal’s resonant frequency.
Once the frequency of the VCO is locked to the series resonant frequency of the crystal, the in-

phase component (at zero phase error, there is no out of phase component) of the crystal current is

demodulated to a DC voltage. This voltage is amplified and converted into resistance value

which the RQCM outputs to the computer.