It makes a covalent bond. This means a bond between a metal and non-metal element.
A bond between carbon and chlorine can be formed through a covalent bond, where they share electrons. One common example is in chloroform (CHCl3), where one carbon atom is bonded to three chlorine atoms through single covalent bonds.
Chlorine and sodium form an ionic bond when they come together to make sodium chloride (table salt). This bond is formed by the transfer of electrons from the sodium atom to the chlorine atom, creating positively and negatively charged ions that are attracted to each other.
Hydrogen and chlorine form a covalent bond when they combine to make hydrogen chloride (HCl). In this type of bond, electrons are shared between the two atoms to achieve a stable electron configuration.
No, it is not difficult to make hydrogen and chlorine bond. They will readily form a covalent bond to create hydrogen chloride gas, which is a simple and common compound.
C represents Carbon, Cl represents Chlorine, therefore C-Cl represents Carbon Tetrachloride. The ionic structure is normally initiated automatically, however some times a little kick is needed (however Chlorine is highly reactive): Carbon has 2 electrons on its innermost shell (2e) then it has 4e (which means it needs 4 to make a complete octet). Carbon- 6 (6 electrons) + Chlorine 17 (17 electrons) -----------------------------------> Carbon- 10 (charge 4-) + Chlorine 13 (charge 4+). Chlorine now has 2e on its innermost shell, then 8e, then 3e. the equation is incomplete because there are 3 electrons left on the outer shell for Chlorine. so if we double it: 2 Carbon- 6 + 2 Chlorine 17 -> 2 Carbon- 10 (4-) + 2 Chlorine 13 (4+) this leaves 6 electrons spare for Chlorine so we double it again: 4 Carbon- 6 + 4 Chlorine 17 -> 4 Carbon- 10 (4-) + 4 Chlorine 13 (4+) this leaves us with 12 spare electrons. 12 spare electrons can be shared equally with 3 Carbon to give them all a full outer shell thus: 7 Carbon + 4 Chlorine -> Carbon Tetrachloride (4X Chloride).
A bond between carbon and chlorine can be formed through a covalent bond, where they share electrons. One common example is in chloroform (CHCl3), where one carbon atom is bonded to three chlorine atoms through single covalent bonds.
covalent bond
Chlorine can form both ionic and covalent bonds, with metals and non-metals respectively.
Chlorine and sodium form an ionic bond when they come together to make sodium chloride (table salt). This bond is formed by the transfer of electrons from the sodium atom to the chlorine atom, creating positively and negatively charged ions that are attracted to each other.
Hydrogen and chlorine form a covalent bond when they combine to make hydrogen chloride (HCl). In this type of bond, electrons are shared between the two atoms to achieve a stable electron configuration.
No, it is not difficult to make hydrogen and chlorine bond. They will readily form a covalent bond to create hydrogen chloride gas, which is a simple and common compound.
A covalent bond
Chlorine and carbon
C-C is a single-bond carbon C=C is a double-bond carbon... soooo.. if you need a triple-bond carbon make the hyphen thrice..
C represents Carbon, Cl represents Chlorine, therefore C-Cl represents Carbon Tetrachloride. The ionic structure is normally initiated automatically, however some times a little kick is needed (however Chlorine is highly reactive): Carbon has 2 electrons on its innermost shell (2e) then it has 4e (which means it needs 4 to make a complete octet). Carbon- 6 (6 electrons) + Chlorine 17 (17 electrons) -----------------------------------> Carbon- 10 (charge 4-) + Chlorine 13 (charge 4+). Chlorine now has 2e on its innermost shell, then 8e, then 3e. the equation is incomplete because there are 3 electrons left on the outer shell for Chlorine. so if we double it: 2 Carbon- 6 + 2 Chlorine 17 -> 2 Carbon- 10 (4-) + 2 Chlorine 13 (4+) this leaves 6 electrons spare for Chlorine so we double it again: 4 Carbon- 6 + 4 Chlorine 17 -> 4 Carbon- 10 (4-) + 4 Chlorine 13 (4+) this leaves us with 12 spare electrons. 12 spare electrons can be shared equally with 3 Carbon to give them all a full outer shell thus: 7 Carbon + 4 Chlorine -> Carbon Tetrachloride (4X Chloride).
Phosphorus and chlorine can form an ionic bond to create phosphorus trichloride (PCl3) or a covalent bond to create phosphorus pentachloride (PCl5), depending on the reaction conditions.
Chlorine and carbon "mixed together" simply make a mixture, but chlorine and carbon reacted with each other make a class of compounds called "chlorocarbons", of which carbon tetrachloride is the member with the smallest molecules.