It needs just one electron to acquire a complete and stable outer shell.
Chlorine readily accepts another electron to achieve a stable electron configuration with a full outer shell of electrons, similar to the noble gas configuration. By gaining an electron, chlorine can achieve a complete octet, which is a more energetically favorable and stable state for the atom.
False. Sodium tends to lose an electron to form a positive ion, while chlorine tends to gain an electron to form a negative ion. This opposite transfer of electrons is what allows sodium and chlorine to readily combine and form salt (sodium chloride).
Sodium (Na) would bond ionically with chlorine (Cl) to form sodium chloride (NaCl). Sodium has an extra electron to give, while chlorine is readily able to accept an electron to complete its outer electron shell, resulting in the transfer of an electron from sodium to chlorine to form a stable ionic bond.
Oh, dude, chlorine reacts readily because it's like that friend who always wants to be the center of attention at a party. It's super electronegative, so it's always looking to steal electrons from other elements to feel complete. Basically, chlorine is just a drama queen in the world of chemistry.
Chlorine is highly reactive because it readily accepts electrons to achieve a stable electron configuration. It can react with a wide range of elements and compounds to form various products, including chlorides.
Chlorine readily gains an electron to form a chloride ion with a negative charge of -1.
Chlorine readily forms chloride ions by gaining an electron to achieve a stable electron configuration. This results in the formation of a negatively charged Cl- ion.
Chlorine readily accepts another electron to achieve a stable electron configuration with a full outer shell of electrons, similar to the noble gas configuration. By gaining an electron, chlorine can achieve a complete octet, which is a more energetically favorable and stable state for the atom.
It needs just one electron to acquire a complete and stable outer shell.
Sodium easily loses one electron to achieve a stable electron configuration, while chlorine readily gains one electron to achieve the same. This exchange of electrons allows sodium to become a positively charged ion and chlorine to become a negatively charged ion, resulting in the formation of a strong ionic bond between them.
False. Sodium tends to lose an electron to form a positive ion, while chlorine tends to gain an electron to form a negative ion. This opposite transfer of electrons is what allows sodium and chlorine to readily combine and form salt (sodium chloride).
Chlorine atom has 17 electrons. It is readily accepting an electron from another atom to obtain its stable electron configuration (of argon). A chloride ion has 18 electrons.
Sodium is a metal, whereas chlorine is a non-metal. Sodium has a single electron in its outer shell, while chlorine has seven electrons in its outer shell. Sodium is highly reactive and readily loses its outer electron, whereas chlorine is highly reactive and readily gains an electron to complete its outer shell.
Chlorine most readily accepts electrons among silicon, sulfur, chlorine, and phosphorus. Chlorine is a halogen and has a high electron affinity due to its high electronegativity, making it more likely to accept electrons to achieve a stable electron configuration. Silicon, sulfur, and phosphorus are nonmetals with varying electron affinities but are generally less likely to accept electrons compared to chlorine.
Chlorine (Cl2) is not an ionic compound. It is a covalently bonded element. Chlorine can form ionic compounds like NaCl (Sodium Chloride) or CaCl2 (Calcium Chloride) but is not itself an ionic compound.
Sodium (Na) would bond ionically with chlorine (Cl) to form sodium chloride (NaCl). Sodium has an extra electron to give, while chlorine is readily able to accept an electron to complete its outer electron shell, resulting in the transfer of an electron from sodium to chlorine to form a stable ionic bond.
Iodide (I⁻) has a negative charge of -1. This occurs because it gains an extra electron, resulting in a net negative charge. As a halogen, iodide readily accepts an electron to achieve a stable electron configuration.