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This element is a metalloid.
A gas is usually a poor conductor of electricity. In contrast, a brittle solid material that is a poor conductor of electricity is typically an insulator.
Antimony is a metalloid that combines with oxygen to create antimony trioxide, which acts as a flame retardant by releasing water vapor when exposed to fire.
The operating temperature of a semiconductor is the temperature at which a semiconductors exhibits the properties of a normal conductor.
Antimony is a metalloid which means that it has metallic and nonmetallic properties and it is element 51 in the periodic table lying in the diagonal metalloids in the p group. The metallic and nonmetallic properties may be, for example, that it is grey and shiny like a metal but it may also be brittle and not conduct heat and electricity like a nonmetal.
Silicon is classified as a metalloid or a semimetal. It exhibits properties of both metals and nonmetals.
metal and a metalloid is both a conductor.
No, antimony is not a good conductor of electricity. It is classified as a metalloid and exhibits semiconductor properties.
A gas is usually a poor conductor of electricity. In contrast, a brittle solid material that is a poor conductor of electricity is typically an insulator.
Aluminum acts as a temperature conductor, meaning it's able to retain.
Nothing. It is at room temperature.
This element is a metalloid.
Boron is classified as a metalloid element. It has properties that are intermediate between metals and nonmetals.
Yes,it should be,although it is not a good one,because it is a metalloid.
silicon is a better conductor of electric current than sulfur is.
Aluminum is not considered a metalloid; it is classified as a metal. It is a good conductor of electricity and heat, and exhibits metallic properties such as luster and malleability.
Silicon acts as a conductor when it is doped with elements that have extra electrons (n-type doping) or when it is exposed to high temperature and light, which generates additional charge carriers. In these cases, silicon can conduct electricity because it has mobile charge carriers that can move freely through the material.