Chlorine (element symbol Cl) has a weight of 35.45 grams per mole, using 4 significant figures. This corresponds to its weight as a gas at STP conditions and a volume of 22.4 liters.
The gram molecular mass of chlorine is 35.4*2 because chlorine is a diatomic element
The Molar Mass is 71.0 g
35.5
2.86 (apex)
Atomic weight of carbon: [12,0096; 12,0116]. Atomic weight of chlorine: [35,446; 35,457]. The molar mass of chlorine is greater; rounded 35,45 g/mol.
4.005
The molar mass of sulfur is 32.065. Molar mass is the mass per mole of a substance. In other words, Molar Mass = Mass/Amount of Substance.
Bromine (Br) has a molar mass of 79.904 amu (atomic mass units), which is extremely close to 80. Bromine is diatomic so when two bromine molecules are put together to create a diatomic gas, the molar masses of each bromine add to get a combined molar mass of 160 amu.
The rate of diffusion of a gas depends on the weight of the gas molecules. The heavier the molecules, the slower they move - the lighter the molecules, the faster they move. Nitrogen molecules weigh about 28 units. Chlorine molecules weigh 71 units. So we would expect nitrogen to diffuse more quickly than chlorine.
2.86
2.86 (apex)
Chlorine is non metal element. Atomic mass of it is 35.
Yes as is the molar mass of anything else.
Atomic weight of carbon: [12,0096; 12,0116]. Atomic weight of chlorine: [35,446; 35,457]. The molar mass of chlorine is greater; rounded 35,45 g/mol.
The weight of chlorine gas can vary depending on the volume and temperature. At standard temperature and pressure (STP), the molar mass of chlorine gas (Cl2) is approximately 70.91 grams/mol. To convert this to pounds, you would divide the molar mass by the conversion factor of 453.592 grams per pound. Therefore, the weight of chlorine gas would be approximately 0.156 pounds per mol at STP.
4.005
Molar mass of NH3 = 17.03052g/mol
you mean to say chlorine... and it 35.45g/mol
The rate of diffusion of a gas is inversely proportional to the square root of the molar mass of that gas. So, lighter gases will diffuse faster than heavier gases. The molar mass for N2 gas is 28 g/mole and that for Cl2 gas is about 71 g/mol, so N2 will diffuse faster.
To calculate the density of chlorine relative to air, you would use the formula: Density relative to air = Density of chlorine gas Density of air at the same conditions Density relative to air= Density of air at the same conditions Density of chlorine gas β The density of a gas can be calculated using the ideal gas law: Density = Molar mass Molar volume Density= Molar volume Molar mass β Where: Molar mass is the mass of one mole of the substance (in grams per mole). Molar volume is the volume occupied by one mole of the substance at a particular temperature and pressure. For chlorine gas ( οΏ½ οΏ½ 2 Cl 2 β ), the molar mass is approximately 70.91 β g/mol 70.91g/mol. The density of air is typically around 1.225 β kg/m 3 1.225kg/m 3 at standard temperature and pressure (STP), which is defined as 0 , ^\circ \text{C} (273.15 K) and 1 β atm 1atm pressure. So, to find the density of chlorine gas relative to air, you would substitute the values into the formula: Density relative to air = ( 70.91 β g/mol ) ( 1.225 β kg/m 3 ) Γ ( 1 β mol 1000 β g ) Density relative to air= (1.225kg/m 3 ) (70.91g/mol) β Γ( 1000g 1mol β ) This calculation will give you the density of chlorine gas relative to air under the specified conditions. Keep in mind that the densities and conditions may vary, and you should use the appropriate values for the specific conditions you are considering.