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The electrode can be made of any metal, but gold is the most common choice because it does not oxidize in air. If gold is used, a thin "undercoat" of chromium is usually put onto the quartz first. This is because gold by itself does not stick all that strongly to quartz. However, chromium sticks well to both gold and quartz. So using a chromium undercoat improves adhesion.
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In vacuum systems, one usually wants to know the mass deposited on a sample by a sputtering or thermal evaporation system. In that case the QCM is put near the sample, in similar conditions. If the deposition rate at the QCM is not the same as that at the sample, a correction factor ("tooling factor") is needed. Then one can monitor the amount of material put on the sample. Devices that do this are called thickness monitors or deposition monitors. If the frequency change of the QCM is used to control the deposition system so as to deposit a predetermined amount of material on the sample the device is typically called a thickness controller or a rate controller. These devices are widely used by the optical coating industry.
With the discovery that QCMs can be made to oscillate in liquids, it became practical to use them to measure the amount of material electrochemically deposited on the QCM. It is also possible to simultaneously measure the charge transferred to or from the electrode. I believe that most of these systems are used for research. However, IBM has used electrochemical QCMs to monitor the thickness of thin film read-write heads for hard drives.
QCMs have been used to make "sniffers". This is done by having an array of QCMs, each topped with a different thin film which absorbs a particular set of chemicals. When these chemicals are present in the environment they are absorbed, increasing the mass of the QCM and decreasing its resonant frequency. The pattern of which sensor's frequency decrease gives information about what chemicals are present in the environment. People who build these things sometimes say they have invented an "electronic nose" or e-nose. Most of these are research gadgets, but there are companies that sell QCM sniffers for monitoring air pollution. Several other technologies are used to build e-noses.
In a related use, it is possible to attach antibodies to the top of a QCM that will bind to, say, a single protein. That makes the QCM an extremely sensitive detector of this protein.
The Pathfinder mission on Mars used a QCM to measure how fast dust settles onto surfaces on Mars..
T = 2L/v.
The nth standing wave has n nodes, and n+1/2 wavelengths fit within L so that its period T is
T = 2L/(n+1)v .
What about an overlayer? In general the frequency shift will depend upon the elastic properties of the overlayer, as well as its density and thickness. However the simplest situation is that in which the overlayer has the same properties as quartz. Then the increase in the period of mode n is Delta T where
Delta T = 2 Delta L / (n+1)v.
So Delta T/T = Delta L/L .
We then notice that there is still a condition of no shear at the top of the overlayer. Thus if the overlayer is thin, it will not be stretched very much. Thus for thin enough overlayers the elastic properties will not be very important and Delta T is proportional to the added mass per unit area. Thus we rewrite our Delta T for a quartz overlayer in terms of the added mass per unit area of a quartz overlayer, and hope that the resulting equation works fairly well for all overlayers that are not too thick. We get
Delta T /T =~ (D Delta L)/(Dq L)),
where D is the density of the overlayer and Dq is the density of quartz. This relationship is generally okay up to Delta T / T = 10% in thickness monitors. Actually, it is better than the original approximate relationship found by Sauerbrey, according to which the decrease in frequency was proportional to the added mass per unit area.
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Boundary conditions must be imposed at the top and bottom of the stack, and at the interfaces between layers. At interfaces one would normally impose two boundary conditions. One would be a "no-slip" boundary condition. The second condition is continuity of horizontal stress.
The no-slip condition simply says that, if two layers are adjacent, the displacement of the top of the lower layer equals the displacement of the bottom of the upper layer. That is, one layer does not slip over the other. (It has been questioned whether the no-slip condition is always true.)
The continuity of stress across the boundary is just Newton's Third Law of Motion in disguise. It says that, if two layers A and B are adjacent, the force per unit area which layer A exerts on layer B equals the force per unit area which layer B exerts on layer A.
The boundary condition to be used at the top of the stack depends on whether the uppermost layer of the stack is considered to be bounded by vacuum or to extend upward forever. If it extends upwards forever (this could be appropriate for a QMB with one side immersed in a fluid), and the top layer is at all lossy, the boundary condition is that the displacement is finite at y equals positive infinity, meaning that the solution in the uppermost layer must attenuate in the +y direction. If the uppermost layer is considered to extend forever, and is not lossy, the boundary condition to be used is that the solution in the uppermost layer must propagate upward. If the uppermost layer is bounded on top by vacuum, the boundary condition is that its interface with vacuum must be "zero-stress" because the vacuum cannot exert a force on it.
The same considerations apply for the boundary condition at the bottom, with appropriate changes in signs. If the bottom layer is bounded by vacuum, the condition at its bottom must be the zero stress condition.
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Here's the source code. It's in C, and zipped (10.4kB). These files are provided on an as is basis. I decline accept responsibility for any problems that may be caused by their use or mis-use.
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- "Linear Piezoelectric Plate Vibrations" by H. F. Tiersten. (Plenum, New York, 1969) Treats the mathematics of piezoelectricity in detail. A valuable resource for theoretical work on QCMs. Difficult to read. Does not mention QCMs.
- "IEEE Standard on Piezoelectricity", copyright 1978 by the Institute of Electrical and Electronics Engineers, Inc. ANSI/IEEE Std 176-1978. IEEE Transactions on Sonics and Ultrasonics, SU-31, No. 2, Part II, March 1984. 55 pages. Similar notation to Tiersten, but easier to read.
- "Introduction to Quartz Crystal Design" by Virgil E. Bottom. (van Nostrand Reinhold, New York, 1986) Moderately Mathematical. Has a few mistakes in derivations. Well written. Discusses quartz and numerous piezoelectric devices in detail. Gives information important to experimentalists. Does not mention QCMs.
- G. Sauerbrey. Z. Phys., 155 206 (1959) The original paper proposing QCMs.
- C. Lu and D. Lewis. J. Appl. Phys., 43 4383 (1972) This paper was not the first to correctly analyze QCMs with a single solid overlayer in the "mechanical model", but it was the first to reduce the results to a simple transcendental formula.
- E. Benes. Discusses QCMs based on a transmission line analogy. Piezoelectric coupling is included using an analogy to transformers.
- C. E. Reed, K. K. Kanazawa and J. H. Kaufman. J. Appl. Phys., 68 1993 (1990) Discusses QCMs from a physical point of view including piezoelectric coupling.
- Z. Lin and M. D. Ward, Analytical Chem., 67 685 (1995). This paper provides experimental evidence that a QCM operating in a liquid can emit sound waves into the liquid, producing extra losses.
- Many additional references, especially on the use of QCMs by chemists, can be found in Georgia Arbuckle's qcm bibliography
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