When an ideal gas at an initial volume of 'V' and pressure of 'P' is isothermally (constant temperature) compressed to V/4. What is the new pressure?
When an ideal gas at an initial volume of 'V' and pressure of 'P' is isothermally...
1.2 moles of ideal gas in a cylinder are compressed isothermally from an initial pressure of 120 kPa and a volume of 0.025 m3 to a final volume of 0.004 m3. Calculate the temperature and the final pressure of the gas; and also estimate the work done on the gas.
The ideal gas in a tank originally has a volume of V= 10.0 cm3, P=105 Pa, and T=27°C. It is compressed isothermally to 2.0 cm3. What is the new temperature? What is the new pressure?
105Pa, initial temperature T-300K, and an initial 1. An ideal gas with initial pressure 2 volume V - 1m3 expands isothermally to a final volume of 2m3. Then, the gas returns to its initial state, first by constant pressure (isobaric) contraction, and then by a change at constant volume (isochoric) a) Draw a PV diagram of this process. What's the total change in thermal energy of the entire process? b) What's the work done by the environment on the gas?...
A gas with initial conditions (P,V,T)i expands isothermally until the final volume=7.645 times the initial volume. What is the ratio of the final pressure to the intial pressure?
A fixed amount of ideal gas is held in a sealed container. The initial volume, pressure, and temperature are [recall that 1L = 10−3 m3, and 1atm = 101,300Pa] V = 40 L P = 2.5 atm T = 400 K. (a) Compute the new temperature if the pressure is reduced to P = 1.0atm while the volume is held constant. (b) Compute the new volume if the temperature increases to 600K while the pressure is reduced to 2.0atm. (c)...
The ideal gas law (PV=nRT) describes the relationship among pressure P, volume V, temperature T, and molar amount n. Fix n and V When n and V are fixed, the equation can be rearranged to take the following form where k is a constant: PT=nRV=k or (PT)initial=(PT)final This demonstrates that for a container of gas held at constant volume, the pressure and temperature are directly proportional.The relationship is also called Gay-Lussac's law after the French chemist Joseph-Louis Gay-Lussac, one of...
Please help with number 2 When an ideal gas is compressed isothermally to 45% of its initial volume, the change in the molar entropy of the gas is ______________ J middot K^-1 middot mol^-1. On the phase diagram shown below segment __________ corresponds to the conditions of temperature and pressure under which the liquid and the solid states of the substance are in equilibrium. AB AC AD
Ideal gas law is given as P.V = n.R.T where P is pressure, V is volume, n is mol number, T is temperature, and R is the ideal gas constant. Using the dimensional homogeneity, find the dimension and the unit of R.
An ideal gas is compressed isothermally from 8.07 L to 6.35 L, at a starting pressure of 0.467 atm and temperature of 78.00 °C. 1. How many moles of gas are present? Tries 0/3 2. What is the final pressure (in atm) of the gas? Tries 0/3 3. If the compression is carried out reversibly and isothermally, how much work (in J) is done on the system? Tries 0/3 4. What is the heat flow in part 3? Remember that...
physic 3. 2 moles of an ideal gas at 17°C has a pressure of 760mm mercury, and is compressed once isothermally and then adiabatically until its volume is halved in each case reversibly and from identical initial conditions). The gas constant is 8.314J/kg. The density of the mercury is 13.60g/cm? [Express all your answers in MKS units e.g. volume in cubic meter, pressure in Pascal, Temperature in Kelvin, etc.) (a) Express the pressure of the gas in units of Pascal....