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
44.98kpa
14kpa
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
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)
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.
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