Electrical Breakdown and Failure of Dielectrics

As you know, the first law of Materials science is "Everything can be broken". Dielectrics are no exception to this rule. If you increase the voltage applied to a capacitor, eventually you will produce a big bang and a lot of smoke - the dielectric material inside the capacitor will have experienced "electrical breakdown" or electrical break-through, an irreversible and practically always destructive sudden flow of current.
The critical parameter is the field strength E in the dielectric. If it is too large, breakdown occurs. The (DC) current vs. field strength characteristic of a dielectric therefore may look look this:
After reaching Ecrit, a sudden flow of current may, within very short times (10–8 s) completely destroys the dielectric to a smoking hot mass of undefinable structure.
Unfortunately, Ecrit is not a well defined material property, it depends on many parameters, the most notable (besides the basic material itself) being the production process, the thickness, the temperature, the internal structure (defects and the like), the age, the environment where it is used (especially humidity) and the time it experienced field stress.
In the cases where time plays an essential role, the expression "failure" is used. Here we have a dielectric being used at nominal field strength well below its breakdown field-strength for some time (usually many years) when it more or less suddenly "goes up in smoke". Obviously the breakdown field strength decreases with operating time - we observe a failure of the material.
In this case the breakdown may not be explosive; but a leakage current may develop which grows over time until a sudden increase leads to total failure of the dielectric.
The effect can be most easily tested or simulated, by impressing a constant (small) current in the dielectric and monitoring the voltage needed as a function of time. A typical voltage time curve may look like this:
A typical result is that breakdown of a "good" dielectric occurs after - very roughly - 1 C of charge has been passed.
The following table gives a rough idea of critical field strengths for certain dielectric materials
Material Critical Field Strength
[kV/cm]
Oil 200
Glass, ceramics 200...400
Mica 200...700
Oiled paper 1800
Polymers 50...900
SiO2 in ICs > 10 000
The last examples serves to remind you that field strength is something totally different from voltage! Lets look at typical data from an integrated memory circuit, a so- called DRAM, short for Dynamic Random Access Memory. It contains a capacitor as the central storage device (no charge = 1; charge = 0). This capacitor has the following typical values:
Capacity » 30 fF (femtofarad)
Dielectric: ONO, short for three layers composed of Oxide (SiO2), Nitride (Si3N4) and Oxide again - together about 8 nm thick!
Voltage: 5 V, and consequently
Field strength E = 5/8 V/nm » 6 · 106 V/cm.
This is far above the critical field strength for practically all bulk materials! We see very graphically that high field strength and voltage have nothing to do with each other. We also see for the first time that materials in the form of a thin film may have properties quite different from their bulk behavior - fortunately they are usually much "better".
Last, lets just note in passing, that electrical breakdown is not limited to insulators proper. Devices made from "bad " conductors - i.e. semiconductors or ionic conductors - may contain regions completely depleted of mobile carriers - space charge regions at junctions are one example.
These insulating regions can only take so much field strength before they break down, and this may severely limit their usage in products
 

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© H. Föll (Semiconductor Technology - Script)