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SCIENCE Test 1: Passage 6.

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Presentation on theme: "SCIENCE Test 1: Passage 6."— Presentation transcript:

1 SCIENCE Test 1: Passage 6

2 Passage 6 Three experiments were done using CO2, krypton (Kr), or O2. For each gas: 1. A 3 L steel vessel was fitted with a cap that contained a gas inlet valve and a pressure and temperature sensor. 2. Air was pumped out of the vessel until the pressure measured 0.00 torr. 3. The vessel was placed on a balance, and the balance was reset to g. 4. Some of the gas was added to the vessel. 5. When the gas in the vessel reached room temperature (22°C), mass and pressure were recorded. 6. Steps 4 and 5 were repeated several times. The experiments were then repeated, except that a 6 L vessel was used (see Figures 1 and 2).

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4 Passage 6 Questions 31. Based on Figure 2, if 13 g of Kr had been added to the 6 L vessel, the pressure would have been: 1. less than 200 torr. 2. between 200 torr and 400 torr. 3. between 400 torr and 600 torr. 4. greater than 600 torr.

5 Passage 6 Questions 31. Based on Figure 2, if 13 g of Kr had been added to the 6 L vessel, the pressure would have been: 1. less than 200 torr. 2. between 200 torr and 400 torr. 3. between 400 torr and 600 torr. 4. greater than 600 torr.

6 Passage 6 Questions 31. Based on Figure 2, if 13 g of Kr had been added to the 6 L vessel, the pressure would have been: 1. less than 200 torr. 2. between 200 torr and 400 torr. 3. between 400 torr and 600 torr. 4. greater than 600 torr. 13

7 Passage 6 Questions 31. Based on Figure 2, if 13 g of Kr had been added to the 6 L vessel, the pressure would have been: 1. less than 200 torr. 2. between 200 torr and 400 torr. 3. between 400 torr and 600 torr. 4. greater than 600 torr. 13

8 Passage 6 Questions 32. Suppose the experiments had been repeated, except with a 5 L vessel. Based on Figures 1 and 2, the pressure exerted by 7 g of CO2 would most likely have been: 1. less than 500 torr. 2. between 500 torr and 1,000 torr. 3. between 1,000 torr and 1,500 torr. 4. greater than 1,500 torr.

9 Passage 6 Questions 32. Suppose the experiments had been repeated, except with a 5 L vessel. Based on Figures 1 and 2, the pressure exerted by 7 g of CO2 would most likely have been: 1. less than 500 torr. 2. between 500 torr and 1,000 torr. 3. between 1,000 torr and 1,500 torr. 4. greater than 1,500 torr. 7

10 Passage 6 Questions 32. Suppose the experiments had been repeated, except with a 5 L vessel. Based on Figures 1 and 2, the pressure exerted by 7 g of CO2 would most likely have been: 1. less than 500 torr. 2. between 500 torr and 1,000 torr. 3. between 1,000 torr and 1,500 torr. 4. greater than 1,500 torr. 1,000 7

11 Passage 6 Questions 32. Suppose the experiments had been repeated, except with a 5 L vessel. Based on Figures 1 and 2, the pressure exerted by 7 g of CO2 would most likely have been: 1. less than 500 torr. 2. between 500 torr and 1,000 torr. 3. between 1,000 torr and 1,500 torr. 4. greater than 1,500 torr. 1,000 7 500 7

12 Passage 6 Questions 32. Suppose the experiments had been repeated, except with a 5 L vessel. Based on Figures 1 and 2, the pressure exerted by 7 g of CO2 would most likely have been: 1. less than 500 torr. 2. between 500 torr and 1,000 torr. 3. between 1,000 torr and 1,500 torr. 4. greater than 1,500 torr. 1,000 7 500 7

13 Passage 6 Questions 33. Based on Figures 1 and 2, for a given mass of O2 at 22°C, how does the pressure exerted by the O2 in a 6 L vessel compare to the pressure exerted by the O2 in a 3 L vessel? In the 6 L vessel, the O2 pressure will be: 1. 12 as great as in the 3 L vessel. 2. the same as in the 3 L vessel. 3. 2 times as great as in the 3 L vessel. 4. 4 times as great as in the 3 L vessel.

14 Passage 6 Questions 33. Based on Figures 1 and 2, for a given mass of O2 at 22°C, how does the pressure exerted by the O2 in a 6 L vessel compare to the pressure exerted by the O2 in a 3 L vessel? In the 6 L vessel, the O2 pressure will be: 1. 12 as great as in the 3 L vessel. 2. the same as in the 3 L vessel. 3. 2 times as great as in the 3 L vessel. 4. 4 times as great as in the 3 L vessel.

15 Passage 6 Questions 33. Based on Figures 1 and 2, for a given mass of O2 at 22°C, how does the pressure exerted by the O2 in a 6 L vessel compare to the pressure exerted by the O2 in a 3 L vessel? In the 6 L vessel, the O2 pressure will be: 1. 12 as great as in the 3 L vessel. 2. the same as in the 3 L vessel. 3. 2 times as great as in the 3 L vessel. 4. 4 times as great as in the 3 L vessel. 1500 750

16 Passage 6 Questions 33. Based on Figures 1 and 2, for a given mass of O2 at 22°C, how does the pressure exerted by the O2 in a 6 L vessel compare to the pressure exerted by the O2 in a 3 L vessel? In the 6 L vessel, the O2 pressure will be: 1. 12 as great as in the 3 L vessel. 2. the same as in the 3 L vessel. 3. 2 times as great as in the 3 L vessel. 4. 4 times as great as in the 3 L vessel. 1500 800 750 400

17 Passage 6 Questions 34. Which of the following best explains why equal masses of O2 and CO2 at the same temperature and in the same-size vessel had different pressures? The pressure exerted by the O2 was: 1. less, because there were fewer O2 molecules per gram than there were CO2 molecules per gram. 2. less, because there were more O2 molecules per gram than there were CO2 molecules per gram. 3. greater, because there were fewer O2 molecules per gram than there were CO2 molecules per gram. 4. greater, because there were more O2 molecules per gram than there were CO2 molecules per gram. CO2 molecules O2 molecules

18 Passage 6 Questions 35. Suppose the experiment involving O2 and the 6 L vessel had been repeated, except at a room temperature of 14°C. For a given mass of O2, compared to the pressure measured in the original experiment, the pressure measured at 14°C would have been: 1. less, because pressure is directly proportional to temperature. 2. less, because pressure is inversely proportional to temperature. 3. greater, because pressure is directly proportional to temperature. 4. greater, because pressure is inversely proportional to temperature.

19 Passage 6 Questions 35. Suppose the experiment involving O2 and the 6 L vessel had been repeated, except at a room temperature of 14°C. For a given mass of O2, compared to the pressure measured in the original experiment, the pressure measured at 14°C would have been: 1. less, because pressure is directly proportional to temperature. 2. less, because pressure is inversely proportional to temperature. 3. greater, because pressure is directly proportional to temperature. 4. greater, because pressure is inversely proportional to temperature.

20 Passage 6 Questions 35. Suppose the experiment involving O2 and the 6 L vessel had been repeated, except at a room temperature of 14°C. For a given mass of O2, compared to the pressure measured in the original experiment, the pressure measured at 14°C would have been: 1. less, because pressure is directly proportional to temperature. 2. less, because pressure is inversely proportional to temperature. 3. greater, because pressure is directly proportional to temperature. 4. greater, because pressure is inversely proportional to temperature.

21 Passage 6 Questions 35. Suppose the experiment involving O2 and the 6 L vessel had been repeated, except at a room temperature of 14°C. For a given mass of O2, compared to the pressure measured in the original experiment, the pressure measured at 14°C would have been: 1. less, because pressure is directly proportional to temperature. 2. less, because pressure is inversely proportional to temperature. 3. greater, because pressure is directly proportional to temperature. 4. greater, because pressure is inversely proportional to temperature.

22 Passage 6 Questions 35. Suppose the experiment involving O2 and the 6 L vessel had been repeated, except at a room temperature of 14°C. For a given mass of O2, compared to the pressure measured in the original experiment, the pressure measured at 14°C would have been: 1. less, because pressure is directly proportional to temperature. 2. less, because pressure is inversely proportional to temperature. 3. greater, because pressure is directly proportional to temperature. 4. greater, because pressure is inversely proportional to temperature.

23 Passage 6 Questions 35. Suppose the experiment involving O2 and the 6 L vessel had been repeated, except at a room temperature of 14°C. For a given mass of O2, compared to the pressure measured in the original experiment, the pressure measured at 14°C would have been: 1. less, because pressure is directly proportional to temperature. 2. less, because pressure is inversely proportional to temperature. 3. greater, because pressure is directly proportional to temperature. 4. greater, because pressure is inversely proportional to temperature.

24 Passage 6 Questions 35. Suppose the experiment involving O2 and the 6 L vessel had been repeated, except at a room temperature of 14°C. For a given mass of O2, compared to the pressure measured in the original experiment, the pressure measured at 14°C would have been: 1. less, because pressure is directly proportional to temperature. 2. less, because pressure is inversely proportional to temperature. 3. greater, because pressure is directly proportional to temperature. 4. greater, because pressure is inversely proportional to temperature.

25 Passage 6 Questions 35. Suppose the experiment involving O2 and the 6 L vessel had been repeated, except at a room temperature of 14°C. For a given mass of O2, compared to the pressure measured in the original experiment, the pressure measured at 14°C would have been: 1. less, because pressure is directly proportional to temperature. 2. less, because pressure is inversely proportional to temperature. 3. greater, because pressure is directly proportional to temperature. 4. greater, because pressure is inversely proportional to temperature.

26 SCIENCE End of Test 1: Passage 6

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