A gas occupying 2560 ml at 756 mm Hg pressure at standard temperature is transferred to a 4.50 L container , where pressure is 0
1 answer:
121.2 K
<u>Explanation:</u>
P1V1 / T1 = P2V2 / T2
T2 = P2V2T1 / P1V1
P1, V1, T1, P2, V2 are the known quantities
T2 is the unknown quantity.
Standard temperature, T1 = 273 K
Volume, V1 = 2560 ml is converted to litres as 2.56 L
Pressure, P1 = 756 mm Hg is converted into atm as 0.99 atm
P2 = 0.25 atm and V2 = 4.50 L
Now we have to insert these values in the above equation 2 we will get the temperature, T2 as,
T2 =
= 121.2 K
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Answer: -
3.151 M
Explanation: -
Let the volume of the solution be 1000 mL.
At 25.0 °C, Density = 1.260 g/ mL
Mass of the solution = Density x volume
= 1.260 g / mL x 1000 mL
= 1260 g
At 25.0 °C, the molarity = 3.179 M
Number of moles present per 1000 mL = 3.179 mol
Strength of the solution in g / mol
= 1260 g / 3.179 mol = 396.35 g / mol (at 25.0 °C)
Now at 50.0 °C
The density is 1.249 g/ mL
Mass of the solution = density x volume = 1.249 g / mL x 1000 mL
= 1249 g.
Number of moles present in 1249 g = Mass of the solution / Strength in g /mol
=
= 3.151 moles.
So 3.151 moles is present in 1000 mL at 50.0 °C
Molarity at 50.0 °C = 3.151 M