osmotic pressure=CRT x i 25 C to Kelvin = 298K 0.318atm= 0.010 M x 0.08206 x 298 K answer= 1.30
bp= 100.33 degrees Celsius (10.5 ATM= m x .0821 x198.15) (m= .645mol) (Change of Tb= .512 degree Celsius/mol x .645mol) (Change of Tb= .33 degrees Celsius) (.33 + 100= 100.33)
747 mmHg
14kpa
44.98kpa
YES!!! Providing the gas pressure above the water is sufficianelty higher than atmospheric pressure.
If this solution is a mixture you would use Henry's or Raoult's Law. If this is pure water then the answer is already in the question.
108.7
98.6 degrees Fahrenheit = 37 degrees Celsius.
78.9g
32 g KCl
The answer is about 30.9 kJ/mol
Rigid container holds hydrogen gas at a pressure of 3.0 atmospheres and a temperature of 2 degrees Celsius. The pressure if the temperature is raised to 10 degrees Celsius will be 15 atmospheres based on the law of pressure for gas.
A fixed quantity of gas at a constant pressure exhibits a temperature of 27 degrees Celsius and occupies a volume of 10.0 L. Use Charles's law to calculate: the temperature of the gas in degrees Celsius in atmospheres if the volume is increased to 16.0 L
The Celsius scale is in fact based on water, it freezes at 0 degrees and boils at 100 degrees Celsius at 760 mm Hg pressure.
bp= 100.33 degrees Celsius (10.5 ATM= m x .0821 x198.15) (m= .645mol) (Change of Tb= .512 degree Celsius/mol x .645mol) (Change of Tb= .33 degrees Celsius) (.33 + 100= 100.33)
100 degrees Celsius or 212 degrees Fahrenheit
100 degrees Celsius is the boiling point of water, which happens to be 212 degrees Fahrenheit at standard pressure