The mass of 1,00 L of chlorine gas is 3,2 g at 20 oC.
The density of chlorine at 0 0C and normal atmospheric pressure is 3.2 g/L.
The weight of chlorine can vary depending on its concentration and form (gas, liquid, or solid). As a gas at standard conditions, one mole of chlorine (Cl2) weighs about 70.9 grams. To convert this to pounds, you would need to use the molar mass of chlorine and the conversion factor for grams to pounds.
The molar volume of a gas at STP (Standard Temperature and Pressure) is 22.4 L. Ethane gas has a molar mass of 30.07 g/mol. Therefore, the mass of ethane gas in a 5.00 L vessel at STP can be calculated as (5.00 L / 22.4 L) * 30.07 g/mol.
The density of chlorine gas at 7.50 × 10^2 torr and 25.0ºC can be calculated using the ideal gas law. First, convert the pressure to atm (7.50 × 10^2 torr = 0.988 atm). Then, use the ideal gas law equation: PV = nRT and rearrange it to solve for density (density = PM/RT where M is the molar mass of chlorine gas). Substituting the values and calculating will give the density in g/L.
The density of CO gas can be calculated using the formula: density = mass/volume. Given the mass of CO gas (0.196 g) and the volume it occupies (100 ml), we can convert the volume to liters (1 L = 1000 ml) and then calculate the density as 0.196 g / 0.1 L = 1.96 g/L. So, the density of CO gas is 1.96 g/L.
2.86
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.
The density of a gas can be calculated using the ideal gas law equation: density = (PM) / (RT), where P is pressure, M is molar mass, R is the ideal gas constant, and T is temperature in Kelvin. First, convert pressure to atm (7.50*10^-2 atm), temperature to Kelvin (25+273 = 298 K), and the ideal gas constant R = 0.0821 L atm/mol K. Then, plug in the values and calculate. The density of chlorine gas at these conditions will be approximately 3.21 g/L.
The density of chlorine at 0 0C and normal atmospheric pressure is 3.2 g/L.
The weight of chlorine can vary depending on its concentration and form (gas, liquid, or solid). As a gas at standard conditions, one mole of chlorine (Cl2) weighs about 70.9 grams. To convert this to pounds, you would need to use the molar mass of chlorine and the conversion factor for grams to pounds.
The molar volume of a gas at STP (Standard Temperature and Pressure) is 22.4 L. Ethane gas has a molar mass of 30.07 g/mol. Therefore, the mass of ethane gas in a 5.00 L vessel at STP can be calculated as (5.00 L / 22.4 L) * 30.07 g/mol.
3 L / 22.414 /mole = 0.1338 moles of the gas 2 g is 0.1338 moles, or 2/0.1338 = 14.948 g/mole is the molecular weight. ( no real gas this light...methane is closest at 16 g/mole)
Chlorine is a gas at STP. Density is 71/22.4 = 3.17 g/L
This volume is 0,449 L at 0 0C.
The density of CO gas can be calculated using the formula: density = mass/volume. Given the mass of CO gas (0.196 g) and the volume it occupies (100 ml), we can convert the volume to liters (1 L = 1000 ml) and then calculate the density as 0.196 g / 0.1 L = 1.96 g/L. So, the density of CO gas is 1.96 g/L.
The density of chlorine gas at 7.50 × 10^2 torr and 25.0ºC can be calculated using the ideal gas law. First, convert the pressure to atm (7.50 × 10^2 torr = 0.988 atm). Then, use the ideal gas law equation: PV = nRT and rearrange it to solve for density (density = PM/RT where M is the molar mass of chlorine gas). Substituting the values and calculating will give the density in g/L.
The density of chlorine as gas is 3,2 g/L at 0 0C and 101 325 kPa.