Part B For this exercise, you can simulate the described conditions by changing the values in...
For this exercise, you can simulate the described conditions by changing the values in the Run Experiment tool of the Simulation. To be able to measure the effects on the gas volume, slide the Rspd bar in the Properties box to V (L) so that the volume bar is highlighted (turns yellow). In this way, volume becomes the only dependent variable. Note that, when volume is selected with Rspd, its value can no longer be directly controlled. Suppose a piston...
For each exercise, you can simulate the described conditions by changing the values in the Run Experiment tool of the Simulation. To be able to measure the effects on pressure or volume, slide the Rspd bar in the Properties box to either P (atm) or V (L), respectively. The slider bar for either pressure or volume will turn yellow when it is selected, and it becomes the only dependent variable, i.e., the value you measure in response to changing the...
ReviewI Constants Periodic Table The air that surrounds us is mostly empty space, and it can be almost a factor of one thousand less dense than water. Within that mostly empty space, gas molecules are moving around at high speed and colliding with each other, and if you are in an enclosed space, they are also colliding with the walls. We can more easily observe the behavior of a gas by confining it to a container with a known volume,...
For this exercise, you can simulate the described conditions by changing the values in the Run Experiment tool, under the Experiment tab, in the simulation. The temperature changes can be used to qualitatively determine whether an unknown acid is a weak or strong acid by running several neutralization reactions and comparing temperature results from the unknown acids with those of a known strong acid and known weak acid. In the simulation, run four neutralization experiments between 0.120 mol of each...
Let us first examine the behavior of an ideal gas when we force the volume to be a value of our choosing. We can examine how changes to the absolute temperature and number of moles affect the pressure of the gas particles (by selecting pressure with Rspd such that pressure cannot be controlled). Assume that 0.03 mol of helium at a temperature of 275.00 K occupy a volume of 1.40 L. Use the Run Experiment tool in the Simulation to...
In an experiment to simulate conditions within an automobile engine, 0.175 mol of air at a temperature of 710 K and a pressure of 3.10x106 Pa is contained in a cylinder of volume 330 cm3. Then 665 J of heat is transferred to the cylinder. If the volume of the cylinder is constant while the heat is added, what is the final temperature of the air? Assume that the air is essentially nitrogen gas If instead the volume of the...
In an experiment to simulate conditions within an automobile engine, 0.175 mol of air at a temperature of 800 K and a pressure of 3.00×106 Pa is contained in a cylinder of volume 390 cm3 . Then 640 J of heat is transferred to the cylinder. A) If the volume of the cylinder is constant while the heat is added, what is the final temperature of the air? Assume that the air is essentially nitrogen gas. B) If instead the...
Can anyone help me find the answer to this?
Thank you! part B please
View Available Hint(s) The ideal gas law (PV = nRT) describes the relationship among pressure P, volume V, temperature T, and molar amount n. When n and V are fixed, the equation can be rearranged to take the following form where k is a constant: Pfinal = 2.61 atm f = np = k or ( a = ( ) final initial Submit Previous Answers When...
Helium gas at 105.0 kPa and 309.0K is located within a cylinder with a piston. Initially the gas occupies 0.4000 m. While a constant force, F, is applied to the end of the piston so that the pressure inside the cylinder is held constant at 105.0 kPa, 5090.0 J of heat is transferred to the helium gas. The specific enthalpy of helium gas is given by the approximate relation: (kJ/mol) = 0.02087(K) Q=5090.0J Final Conditions P2 = 105.0 kPa Initial...
Part C An ideal gas (which is is a hypothetical gas that conforms to the laws governing gas behavior) confined to a container with a massless piston at the top. (Figure 2) A massless wire is attached to the piston. When an external pressure of 2.00 atm is applied to the wire, the gas compresses from 4.90 to 2.45 L . When the external pressure is increased to 2.50 atm, the gas further compresses from 2.45 to 1.96 L ....