since a positively charged ion will be attracted to a negatively charged ion, when they come together they form a compound with different characteristics than the elements the ions came from.
take table salt for example. it's an ionic compound. NaCl = Sodium chloride is its real name and they come together since a sodium atom is positively charged and a chlorine atom is negatively charged. when they come together they form NaCl.
Ionic compounds typically have higher conductivity than molecular compounds because ionic compounds dissociate into ions in solution, allowing for the flow of electric current. Molecular compounds, on the other hand, do not dissociate into ions in solution and therefore exhibit lower conductivity.
Molecular compounds in water form solutions where the molecules remain intact and dispersed individually. Ionic compounds, on the other hand, dissociate into ions when in water, resulting in conductive solutions due to the presence of charged particles. Additionally, molecular compounds generally do not conduct electricity in solution.
True. In an aqueous solution of ionic compounds, the positive and negative ions will attract each other due to their opposite charges, forming electrostatic bonds known as dipole attractions.
Cations in a solution are typically associated with a positive charge.
The differences in properties between ionic and molecular compounds are primarily due to the nature of their chemical bonding. Ionic compounds have strong electrostatic attractions between oppositely charged ions, leading to high melting and boiling points, as well as conductivity in solution. In contrast, molecular compounds have weaker intermolecular forces, resulting in lower melting and boiling points, and most are not conductive in solution.
Covalently bonded compounds are characterized by a molecular formula, because such compounds exist in the form of discrete molecules, all of the atoms of which move together as kinetic-molecular units. Ionically bonded compounds do not have molecules in this sense: Their compounds are made up of at least two kinds of ions, one positive and the other negative, and the ions in these compounds can move separately as kinetic-molecular units: If a positive ion is separated from the particular negative ion with which it was most closely associated initially in a fluid mixture, usually a solution in an ionizing solvent, of both kinds of ions, another negative ion with the same properties is always close by.
Salts produce (metallic) positive catIONS and negative anIONS (of non-metals)
Ionic compounds typically have higher conductivity than molecular compounds because ionic compounds dissociate into ions in solution, allowing for the flow of electric current. Molecular compounds, on the other hand, do not dissociate into ions in solution and therefore exhibit lower conductivity.
the molecular compound in solution gets converted into amoino acid
Ionic compounds dissociate in water to form positive and negative ions in aqueous solution. Such solutions can conduct electricity.
Molecular compounds in water form solutions where the molecules remain intact and dispersed individually. Ionic compounds, on the other hand, dissociate into ions when in water, resulting in conductive solutions due to the presence of charged particles. Additionally, molecular compounds generally do not conduct electricity in solution.
True. In an aqueous solution of ionic compounds, the positive and negative ions will attract each other due to their opposite charges, forming electrostatic bonds known as dipole attractions.
Cations in a solution are typically associated with a positive charge.
Molecular compounds are charge neutral. Molecular compounds dissolve in water as individual molecules. For example if 1.0g of C12H22011 (sucrose or table sugar) dissolves in water the solid will become many individual C12H22011 molecules floating in water but will remain charge neutral. Therefore, this solution does not conduct electricity. This is known as a nonelectrolyte solution. On the other hand, when ionic compounds, like NaCl (table salt), are dissolved in solution they break up into individual ions. In this case Na+ and Cl-. These ions with their respective charges make the solution electrically conductive. This is called an electrolyte solution.
Positive and negative charges.
The differences in properties between ionic and molecular compounds are primarily due to the nature of their chemical bonding. Ionic compounds have strong electrostatic attractions between oppositely charged ions, leading to high melting and boiling points, as well as conductivity in solution. In contrast, molecular compounds have weaker intermolecular forces, resulting in lower melting and boiling points, and most are not conductive in solution.
yes because there is an exchange between the positive and negative plates were the solution will be highly concentrated with negative irons