The chlorine atom would become a negatively charged chlorine anion because it has an extra electron, and the lithium atom would become a positively charged cation because it has lost one electron.
If a fluorine atom were to attract an extra electron from lithium, the lithium atom would become a positive charge. This is because it would lose an electron, leaving it with a net positive charge due to the loss of a negatively charged electron.
If a fluorine atom were to attract an extra electron from a lithium atom, the lithium atom would become a positive charge because it loses an electron.
When lithium forms an ionic bond with fluorine, lithium becomes a positively charged ion. This is because lithium loses an electron to fluorine, which has a higher electronegativity, resulting in the formation of Li+ and F- ions.
The compound formed is lithium fluoride (LiF). This is because lithium loses an electron to become a positively charged ion (Li+) and fluorine gains an electron to become a negatively charged ion (F-), and the resulting compound is neutral with the formula LiF.
In the formation of the binary ionic compound between fluorine and lithium, a lithium atom donates one electron to a fluorine atom. This electron transfer results in the formation of lithium cation (Li+) and fluorine anion (F-). The attraction between the oppositely charged ions leads to the formation of the ionic compound lithium fluoride (LiF).
If a fluorine atom were to attract an extra electron from lithium, the lithium atom would become a positive charge. This is because it would lose an electron, leaving it with a net positive charge due to the loss of a negatively charged electron.
When a fluorine atom attracts an extra electron from a lithium atom, the lithium atom loses one electron and becomes positively charged, forming a lithium ion (Li⁺). Meanwhile, the fluorine atom gains the extra electron, becoming negatively charged and forming a fluoride ion (F⁻). This transfer of electrons results in the formation of an ionic bond between the two ions.
If a fluorine atom were to attract an extra electron from a lithium atom, the lithium atom would become a positive charge because it loses an electron.
If a fluorine atom attracts an extra electron from a lithium atom, the fluorine atom will become negatively charged, forming a fluoride ion (F⁻), while the lithium atom will become positively charged, forming a lithium ion (Li⁺). This process involves the transfer of an electron from lithium to fluorine, resulting in the formation of an ionic bond between the two ions. The overall reaction leads to the formation of a stable ionic compound, lithium fluoride (LiF).
Lithium donates an electron to fluorine, forming lithium cations and fluorine anions that attract each other via ionic bonds. This results in the formation of lithium fluoride, a stable compound that satisfies the octet rule for both lithium and fluorine.
When lithium forms an ionic bond with fluorine, lithium becomes a positively charged ion. This is because lithium loses an electron to fluorine, which has a higher electronegativity, resulting in the formation of Li+ and F- ions.
The compound formed is lithium fluoride (LiF). This is because lithium loses an electron to become a positively charged ion (Li+) and fluorine gains an electron to become a negatively charged ion (F-), and the resulting compound is neutral with the formula LiF.
In the formation of the binary ionic compound between fluorine and lithium, a lithium atom donates one electron to a fluorine atom. This electron transfer results in the formation of lithium cation (Li+) and fluorine anion (F-). The attraction between the oppositely charged ions leads to the formation of the ionic compound lithium fluoride (LiF).
Positively (apex)
The lithium atom would lose an electron to the bromine atom, becoming positively charged. This is because lithium has one valence electron, and by losing it to bromine (which has seven valence electrons and can gain one more to achieve a full octet), lithium forms a cation with a +1 charge.
In the formation of LiF, lithium transfers one electron to fluorine. Lithium donates its one valence electron to fluorine, resulting in lithium becoming a +1 cation (Li+) and fluorine becoming a -1 anion (F-). The resulting ionic compound is held together by the electrostatic attraction between the positively charged lithium ion and the negatively charged fluorine ion.
LiF is an ionic compound. It is formed from the combination of the metal lithium (Li) and the nonmetal fluorine (F), where lithium loses an electron to become a positively charged ion and fluorine gains an electron to become a negatively charged ion, resulting in an electrostatic attraction between the ions.