So being neutral isn't deterring an electron from being added to the atom, rather if it has an effective nuclear charge which is based on the number of protons and core electrons, not the total number of electrons. Even though the lithium atom is neutral (that is has the same number of protons as electrons) a new valance electron feels an effective nuclear charge from the protons because only two of the total electrons are engaging in that shielding effect and therefore the new valence electron would remain bound to the lithium atom. So the effective nuclear charge felt by a new valance electron to a neutral lithium atom is: Zeff = 3 - 2 = 1. So an electron being added to the third shell (the 3s orbital) would feel no attraction to the nucleus and not remain easily bound to the neon atom.īut if we do the same to a neutral atom of lithium with 3 protons, lithium has 3 total electrons, but 2 are core electrons in the first shell and 1 is a valance electron in the second shell. So if we were to add an electron to a neutral atom of neon, neon has 10 protons, and 10 core electrons, so Zeff = 10 - 10 = 0. The formula is given as: Zeff = Z - S, where Zeff is effective nuclear charge, Z is the atomic number (number of protons), and S is the number of core electrons. The shielding effect is technically felt by electrons in lower shells than the electron in question AND other electrons in the same shell, but here on KA Jay is giving a simplified version where only the electrons in lower levels are considered (called core electrons if we're concerned with electrons in the valance shell). ![]() So effective nuclear charge is the attractive electric force an electron feels from the positively charged protons in the nucleus minus the repulsive electric force experienced from other electrons (called the shielding effect). That is quite different from the situation with electronegativity where you are concern with how much the atom "wants" an electron as determined by the molecules it makes. With electron affinity you expose the atom to a source of electrons and see how much energy it releases when it gains an electron (note, gains an electron, not forms a molecule). So, these are rather different situations. There is some correlation, of course, but it is not a strict correspondence. This is not necessarily directly related to the "willingness" for the element to actually acquire an electron when forming a compound (as measured by electronegativity). The electron affinity measures the energy released when an electron is captured by the atom (or a molecule), forming an anion with a 1− charge. ![]() Unlike electronegativity, the electron affinity does not have a strong periodic value. That is why Boron is not usually studied at an introductory level. Boron is a very unusual element, with complicated properties.
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