Each sketch below shows a flask with some gas and a pool of mercury in it. The gas is at a pressure of 0.5 atm. A J-shaped tube is connected to the bottom of the flask, and the mercury can freely flow in or out of this tube. (You can assume that there is so much more mercury in the pool than can fit into the tube that even if the J-tube is completely filled, the level of mercury in the pool won't change.) Notice also that in the left sketch the J-tube is open at its other end, so that air from the atmosphere can freely flow. On the other hand, in the right sketch the J-tube is closed at its other end, and you should assume there is no gas between the mercury and the closed end of the tube. To answer this question, you must decide what the mercury level will be when the mercury finally stops flowing in or out of the tube. By moving the sliders back and forth, you'll see different levels of mercury in the J-tube. Select the final correct level for each sketch. open tube closed tube - 3.0 - 3.0 - 2,5 - 2.5 - 2.0 - 2.0 0.5 atm 0.5 atm - 1.5 m - 1.5 m - 1.0 - 1.0 - 0.5 - 0.5 - 0.0 - 0.0

Each sketch below shows a flask with some gas and a pool of mercury in it. The gas is at a pressure of 0.5 atm. A J-shaped tube is connected to the bottom of the flask, and the mercury can freely flow in or out of this tube. (You can assume that there is so much more mercury in the pool than can fit into the tube that even if the J-tube is completely filled, the level of mercury in the pool won't change.) Notice also that in the left sketch the J-tube is open at its other end, so that air from the atmosphere can freely flow. On the other hand, in the right sketch the J-tube is closed at its other end, and you should assume there is no gas between the mercury and the closed end of the tube. To answer this question, you must decide what the mercury level will be when the mercury finally stops flowing in or out of the tube. By moving the sliders back and forth, you'll see different levels of mercury in the J-tube. Select the final correct level for each sketch. open tube closed tube - 3.0 - 3.0 - 2,5 - 2.5 - 2.0 - 2.0 0.5 atm 0.5 atm - 1.5 m - 1.5 m - 1.0 - 1.0 - 0.5 - 0.5 - 0.0 - 0.0

Chemistry

10th Edition

ISBN:9781305957404

Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

Publisher:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

Chapter1: Chemical Foundations

Section: Chapter Questions

Problem 1RQ: Define and explain the differences between the following terms. a. law and theory b. theory and...

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Say you could capture the carbon dioxide gas produced by the combustion of 1 gallon of octane at 22 degrees Celsius and 1.01 atm. Use the ideal gas law to determine the volume of co2 produced.
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A sample of magnesium metal reacts completely with an excess of hydrocholoric: Mg(s) + 2 HCl(aq) -- > MgCl2(aq) + H2(g) The hydrogen gas produced is collected over water at 28.0 °C. The volume of the gas is 18 L, and the total pressure in the gas collection vessel is 1.06 atm. Calculate the mass of magnesium metal that reacted in grams. (Vapor pressure of water at 28.0 °C = 28.2 mmHg) Just give the number. The assumption is the value is in grams.
The stopcock connecting a 2.48 L bulb containing argon gas at a pressure of 7.94 atm, and a 7.99 L bulb containing neon gas at a pressure of 4.66 atm, is opened and the gases are allowed to mix. Assuming that the temperature remains constant, the final pressure in the system is atm.
A student experimentally determines the gas law constant, R, by reacting a small piece of magnesium with excess hydrochloric acid and then collecting the hydrogen gas over water in a eudiometer. Based L-atm on experimentally collected data, the student calculates R to equal 0.0832 mol·K L-atm Ideal gas law constant from literature: 0.08206 mol·K (a) Determine the percent error for the student's R-value. Percent error = % (b) For the statements below, identify the possible source(s) of error for this student's trial. The student notices a large air bubble in the eudiometer after collecting the hydrogen gas, but does not dislodge it. The student does not clean the zinc metal with sand paper. The student does not equilibrate the water levels within the eudiometer and the beaker at the end of the reaction. The water level in the eudiometer is 1-inch above the water level in the beaker. The student uses the barometric pressure for the lab to calculate R.
A 34.0 L metal cylinder stores a sample of gas at 26 °C under 1.42 atm. The temperature of the storage unit rises to 96 °C, causing the gas to decompose and doubling the number of moles in the cylinder.
A sample of magnesium metal reacts completely with an excess of hydrocholoric acid: Mg(s) + 2 HCl(aq) --> MgCl₂(aq) + H₂(g) The hydrogen gas produced is collected over water at 28.0 °C. The volume of the gas is 52 L, and the total pressure in the gas collection vessel is 1.02 atm. Calculate the mass of magnesium metal that reacted in grams. (Vapor pressure of water at 28.0 °C = 28.2 mmHg) Just give the number. The assumption is the value is in grams.
A student obtained a mass of 0.266 g CO2 during his experiment. The atmospheric pressure was 751.6 mmHg and the laboratory temperature was 24.1 °C. The flask used in the experiment had a volume of 146.5 mL. Calculate the molar mass of CO2 from the data. Hint: You cannot use the molar mass of CO2 in your calculation since this is what you are looking for... You need to used the ideal gas law to determine the number of moles of CO2, then do the ratio of grams of CO2 over moles of CO2 to determine the experimental molar mass of CO2.
Suppose you have a sample of bromine at 1 atm pressure and 298 K. Describe two ways to convert this sample of bromine into a gas. Include in your descriptions what the final pressure and temperature must be in order for the sample to be a gas.
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