No, It is silver metal, an element , single Ag is an atom.
Silver have high affinity toward halogen. Dry silver oxide (Ag2O) reacts with two molecules of (2RX) to give ether and 2AgX. Reaction will be: 2RX + Ag2O = ROR + 2AgX
silvers turn black due to the reaction of sulphur present in hydrogen sulphide from air. --- Tarnish is silver oxide (rust) caused by a chemical reaction of oxygen and hydrogen sulphide with the surface of the silver. Unlike iron, silver will not rust in air absent of hydrogen sulphide.
Ag2O----Actually, silver oxides exists as silver peroxide (AgO) or silver oxide (Ag2O)
The molar mass of silver nitrate is 169,87 g: approx. two formula units.
22.0 g of silver chloride contain 0,918.10e23 molecules.
2 Silver Sulfide molecules (silver tarnish)
No, It is silver metal, an element , single Ag is an atom.
2AgNO2 is two molecules of silver nitrate.
according to Avogadro number, one mole of substance = 6.022x10^23 molecules. so 2 mole =12.044 molecules of substance. the number of molecules don't depend on what the substances are but depends on the number of mole of that substance
Both have polar molecules.
Well, because you have 65g of AgNO3, you have .3826 moles of silver nitrate. This is found by dividing the number of grams you have by the molar mass of silver nitrate (169.9g/mol). Once you know how many moles there are you can then multiply by Avogodro's number (6.022x1023) to obtain the number of molecules. In this case it is 2.304x1023 molecules.
Well, because you have 65g of AgNO3, you have .3826 moles of silver nitrate. This is found by dividing the number of grams you have by the molar mass of silver nitrate (169.9g/mol). Once you know how many moles there are you can then multiply by Avogodro's number (6.022x1023) to obtain the number of molecules. In this case it is 2.304x1023 molecules.
2.0^25 moles of silver nitrate is .0301 moles.
The attractive forces holding the molecules of silver iodide together (intermolecular forces) are stronger than those in vanillin, therefore they require more energy to break them. The attractive forces between two molecules of silver iodide are much stronger than the attractive forces between two molecules of vanilin. This is due to the different types of bonds found in each molecule - silver iodide molecules contain ionic bonds, which are very strong, while vanilin molecules contain covalent bonds which are a lot weaker. Since the attractive forces are higher in silver iodide, it requires a lot more energy (i.e. heat) to break these attractive forces in order to melt silver iodide, therefore it has a much higher melting point than vanilin. The bonding of atoms.
There are a great many molecules in the world. 5 molecules are water, table salt, ozone, carbon dioxide, and silver nitrate.
No, the molecules only compact into more and more dense solids as temperature decreases.