Dielectric strength
In , the term dielectric strength has the following meanings:
- for a pure electrically insulating material, the maximum electric field that the material can withstand under ideal conditions without undergoing electrical breakdown and becoming electrically conductive.
- For a specific piece of dielectric material and location of electrodes, the minimum applied electric field that results in breakdown. This is the concept of breakdown voltage.
Electrical breakdown
is a flow of electrically charged particles in a material caused by an electric field. The mobile charged particles responsible for electric current are called charge carriers. In different substances different particles serve as charge carriers: in metals and other solids some of the outer electrons of each atom are able to move about the material; in electrolytes and plasma it is ions, electrically charged atoms or molecules, and electrons. A substance that has a high concentration of charge carriers available for conduction will conduct a large current with the given electric field created by a given voltage applied across it, and thus has a low electrical resistivity; this is called an electrical conductor. A material that has few charge carriers will conduct very little current with a given electric field and has a high resistivity; this is called an electrical insulator.However when a large enough electric field is applied to any insulating substance, at a certain field strength the concentration of charge carriers in the material suddenly increases by many orders of magnitude, so its resistance drops and it becomes a conductor. This is called electrical breakdown. The physical mechanism causing breakdown differs in different substances. In a solid, it usually occurs when the electric field becomes strong enough to pull outer valence electrons away from their atoms, so they become mobile. The field strength at which breakdown occurs is an intrinsic property of the material called its dielectric strength.
In practical electric circuits electrical breakdown is often an unwanted occurrence, a failure of insulating material causing a short circuit, resulting in a catastrophic failure of the equipment. The sudden drop in resistance causes a high current to flow through the material, and the sudden extreme Joule heating may cause the material or other parts of the circuit to melt or vaporize explosively. However, breakdown itself is reversible. If the current supplied by the external circuit is sufficiently limited, no damage is done to the material, and reducing the applied voltage causes a transition back to the material's insulating state.
Factors affecting apparent dielectric strength
- It decreases with increased sample thickness.
- It decreases with increased operating temperature.
- It decreases with increased frequency.
- For gases it normally decreases with increased humidity as ions in water can provide conductive channels.
- For gases it increases with pressure according to Paschen's law
- For air, dielectric strength increases slightly as the absolute humidity increases but decreases with an increase in relative humidity
Breakdown field strength
Dielectric strength of various common materials:
| Substance | Dielectric strength |
| Helium | |
| Air | 3 |
| Sulfur hexafluoride | 8.5–9.8 |
| Alumina | |
| Window glass | 9.8–13.8 |
| Borosilicate glass | 20–40 |
| Silicone oil, mineral oil | 10–15 |
| Benzene | 163 |
| Polystyrene | |
| Polyethylene | 19–160 |
| Neoprene rubber | 15.7–26.7 |
| Distilled water | 65–70 |
| High vacuum | 20–40 |
| Fused silica | 470–670 |
| Waxed paper | 40–60 |
| PTFE | |
| PTFE | 60–173 |
| PEEK | 23 |
| Mica | 118 |
| Diamond | 2000 |
| PZT | 10–25 |
Units
In SI, the unit of dielectric strength is volts per meter. It is also common to see related units such as volts per centimeter, megavolts per meter, and so on.In United States customary units, dielectric strength is often specified in volts per mil. The conversion is: