6.24151 × 1018 electrons have a charge of minus one coloumb (the coloumb is defined in terms of positive charge). I don't know what you mean by "delocalized", but normally all electrons have the same charge.
Approximately 6.25E18 electrons in a Coulomb.
If the starting point are elements then the inner shell electrons (non valence) these orbit the nuclei of the atoms and the formation of a chemical bond does not affect these materially. What happens to the valence electrons depends on the bond formed. In an ionic bond electrons are transferred from say the metal atom to the nonmetal- these electrons essentially "orbit" the nuclei of the cations and anions. They are "localised". When a covalent bond is formed the valence electrons involved are shared between the atoms, they "orbit" both nuclei. When the bond is polar covalent they spend a little more time nearer the more electronegative element. When a "delocalised"covalent bond is formed as in bezene or graphite the electrons orbit a number of atomic nuclei. In a metallic bond the valence electrons are also delocalised (the sea of electrons model) across the metal lattice, but in transition metals there is additional bonding between electrons in d orbitals (the tight bound electrons) and these electrons are essentially localised.
6.25 x 10 ^18
Clay consists of many different elements, and it is therefore impossible to tell how many electrons it has.
phosphorus will accept 3 electrons or share 3 electrons
There are about 6.24 x 1018 electrons (or protons) in one coulomb of charge.
It takes 6.25E18 electrons to produce 1 coulomb of charge.
Approximately 6.25E18 electrons in a Coulomb.
A metal is normally viewed as cations in a sea of delocalised electrons. It is the metal atoms which donate their valence electrons to the sea of delocalised electrons.
The charge of 96,481 electrons; approximately counted as either 96,490 or 96,500 as per convenience has a charge equivalent to a Coulomb.
10
Because there are a higher amount of delocalised electrons.
Metallic bonding involves delocalised electrons, which can transfer heat and electricity across the metal. Also, graphite and benzene contains delocalised electrons.
Charge on electron = - 1.602 X 10 -19 coulomb, so..., - 58. 0 coulomb/- 1.602 X 10 -19 coulomb = 3.62 X 1020 electrons ===============
6.242 x 1018
Not sure, but maybe you are referring to "lone pair" of electrons.
A coulomb is defined as a positive charge. 1 coulomb is the charge of 6.24 x 1018 protons. Multiply that by a million (106) for your question. However, the same number of electrons would have a charge of minus a million coulomb.