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1 Cloud cover is the percent of Earth’s surface covered by clouds. Cloud cover may increase because of an increase in the cosmic ray flux (number of.

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Presentation on theme: "1 Cloud cover is the percent of Earth’s surface covered by clouds. Cloud cover may increase because of an increase in the cosmic ray flux (number of."— Presentation transcript:

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3 Cloud cover is the percent of Earth’s surface covered by clouds. Cloud cover may increase because of an increase in the cosmic ray flux (number of high-energy particles from space reaching Earth per m 2 per hour). Table 1 shows how Earth’s cover of low clouds (0 km to 3.2 km altitude) varies with the cosmic ray flux. Figures 1−3 show the relative cosmic ray flux, RCRF (the percent below the flux measured on October 1, 1965), and the monthly average cover of high clouds (6.0 km to 16.0 km altitude), middle clouds (3.2 km to 6.0 km altitude), and low clouds, respectively, from January 1980 to January 1995. Table 1 adapted from E. Palle Bagó and C. J. Butler, “The Influence of Cosmic Rays on Terrestrial Clouds and Global Warming.” ©2000 by Institute of Physics Publications, Ltd. Passage 3 2

4 Cloud cover is the percent of Earth’s surface covered by clouds. Cloud cover may increase because of an increase in the cosmic ray flux (number of high-energy particles from space reaching Earth per m 2 per hour). Table 1 shows how Earth’s cover of low clouds (0 km to 3.2 km altitude) varies with the cosmic ray flux. Figures 1−3 show the relative cosmic ray flux, RCRF (the percent below the flux measured on October 1, 1965), and the monthly average cover of high clouds (6.0 km to 16.0 km altitude), middle clouds (3.2 km to 6.0 km altitude), and low clouds, respectively, from January 1980 to January 1995. Table 1 adapted from E. Palle Bagó and C. J. Butler, “The Influence of Cosmic Rays on Terrestrial Clouds and Global Warming.” ©2000 by Institute of Physics Publications, Ltd. Passage 3 3

5 Cloud cover is the percent of Earth’s surface covered by clouds. Cloud cover may increase because of an increase in the cosmic ray flux (number of high-energy particles from space reaching Earth per m 2 per hour). Table 1 shows how Earth’s cover of low clouds (0 km to 3.2 km altitude) varies with the cosmic ray flux. Figures 1−3 show the relative cosmic ray flux, RCRF (the percent below the flux measured on October 1, 1965), and the monthly average cover of high clouds (6.0 km to 16.0 km altitude), middle clouds (3.2 km to 6.0 km altitude), and low clouds, respectively, from January 1980 to January 1995. Table 1 adapted from E. Palle Bagó and C. J. Butler, “The Influence of Cosmic Rays on Terrestrial Clouds and Global Warming.” ©2000 by Institute of Physics Publications, Ltd. Passage 3 4

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10 Figures adapted from Nigel Marsh and Henrik Svensmark, “Low Cloud Properties Influenced by Cosmic Rays.” ©2000 by The American Physical Society. 9

11 13. The percent of Earth’s surface covered by high clouds in January 1987 was closest to which of the following? 1. 13.0% 2. 13.5% 3. 14.0% 4. 14.5% Passage 3 Questions 10

12 13. The percent of Earth’s surface covered by high clouds in January 1987 was closest to which of the following? 1. 13.0% 2. 13.5% 3. 14.0% 4. 14.5% Passage 3 Questions 11

13 13. The percent of Earth’s surface covered by high clouds in January 1987 was closest to which of the following? 1. 13.0% 2. 13.5% 3. 14.0% 4. 14.5% Passage 3 Questions 12

14 14. Based on Table 1, a cosmic ray flux of 440,000 particles/m 2 /hr would correspond to a cover of low clouds that is closest to which of the following? 1. 28.7% 2 29.0% 3. 29.3% 4. 29.6% Passage 3 Questions 13

15 14. Based on Table 1, a cosmic ray flux of 440,000 particles/m 2 /hr would correspond to a cover of low clouds that is closest to which of the following? 1. 28.7% 2 29.0% 3. 29.3% 4. 29.6% Passage 3 Questions 14

16 14. Based on Table 1, a cosmic ray flux of 440,000 particles/m 2 /hr would correspond to a cover of low clouds that is closest to which of the following? 1. 28.7% 2 29.0% 3. 29.3% 4. 29.6% Passage 3 Questions 15 440,000

17 14. Based on Table 1, a cosmic ray flux of 440,000 particles/m 2 /hr would correspond to a cover of low clouds that is closest to which of the following? 1. 28.7% 2 29.0% 3. 29.3% 4. 29.6% Passage 3 Questions 16 440,000 29.3

18 15. Is the statement “The monthly average cover of low clouds is more directly correlated with cosmic ray flux than is the monthly average cover of high clouds” consistent with Figures 1 and 3 ? 1. Yes, because the plot for the monthly average cover of low clouds more closely parallels the plot for RCRF. 2. Yes, because the plot for the monthly average cover of high clouds more closely parallels the plot for RCRF. 3. No, because the plot for the monthly average cover of low clouds more closely parallels the plot for RCRF. 4. No, because the plot for the monthly average cover of high clouds more closely parallels the plot for RCRF. Passage 3 Questions 17

19 15. Is the statement “The monthly average cover of low clouds is more directly correlated with cosmic ray flux than is the monthly average cover of high clouds” consistent with Figures 1 and 3 ? 1. Yes, because the plot for the monthly average cover of low clouds more closely parallels the plot for RCRF. 2. Yes, because the plot for the monthly average cover of high clouds more closely parallels the plot for RCRF. 3. No, because the plot for the monthly average cover of low clouds more closely parallels the plot for RCRF. 4. No, because the plot for the monthly average cover of high clouds more closely parallels the plot for RCRF. Passage 3 Questions 18

20 15. Is the statement “The monthly average cover of low clouds is more directly correlated with cosmic ray flux than is the monthly average cover of high clouds” consistent with Figures 1 and 3 ? 1. Yes, because the plot for the monthly average cover of low clouds more closely parallels the plot for RCRF. 2. Yes, because the plot for the monthly average cover of high clouds more closely parallels the plot for RCRF. 3. No, because the plot for the monthly average cover of low clouds more closely parallels the plot for RCRF. 4. No, because the plot for the monthly average cover of high clouds more closely parallels the plot for RCRF. Passage 3 Questions 19

21 15. Is the statement “The monthly average cover of low clouds is more directly correlated with cosmic ray flux than is the monthly average cover of high clouds” consistent with Figures 1 and 3 ? 1. Yes, because the plot for the monthly average cover of low clouds more closely parallels the plot for RCRF. 2. Yes, because the plot for the monthly average cover of high clouds more closely parallels the plot for RCRF. 3. No, because the plot for the monthly average cover of low clouds more closely parallels the plot for RCRF. 4. No, because the plot for the monthly average cover of high clouds more closely parallels the plot for RCRF. Passage 3 Questions 20

22 15. Is the statement “The monthly average cover of low clouds is more directly correlated with cosmic ray flux than is the monthly average cover of high clouds” consistent with Figures 1 and 3 ? 1. Yes, because the plot for the monthly average cover of low clouds more closely parallels the plot for RCRF. 2. Yes, because the plot for the monthly average cover of high clouds more closely parallels the plot for RCRF. 3. No, because the plot for the monthly average cover of low clouds more closely parallels the plot for RCRF. 4. No, because the plot for the monthly average cover of high clouds more closely parallels the plot for RCRF. Passage 3 Questions 21

23 15. Is the statement “The monthly average cover of low clouds is more directly correlated with cosmic ray flux than is the monthly average cover of high clouds” consistent with Figures 1 and 3 ? 1. Yes, because the plot for the monthly average cover of low clouds more closely parallels the plot for RCRF. 2. Yes, because the plot for the monthly average cover of high clouds more closely parallels the plot for RCRF. 3. No, because the plot for the monthly average cover of low clouds more closely parallels the plot for RCRF. 4. No, because the plot for the monthly average cover of high clouds more closely parallels the plot for RCRF. Passage 3 Questions 22

24 16.Which of the following figures best represents the monthly average cover of high, middle, and low clouds in January 1992 ? Passage 3 Questions 23

25 16.Which of the following figures best represents the monthly average cover of high, middle, and low clouds in January 1992 ? Passage 3 Questions 24

26 16.Which of the following figures best represents the monthly average cover of high, middle, and low clouds in January 1992 ? Passage 3 Questions 25

27 16.Which of the following figures best represents the monthly average cover of high, middle, and low clouds in January 1992 ? Passage 3 Questions 26

28 16.Which of the following figures best represents the monthly average cover of high, middle, and low clouds in January 1992 ? Passage 3 Questions 27

29 16.Which of the following figures best represents the monthly average cover of high, middle, and low clouds in January 1992 ? Passage 3 Questions 28

30 17. High clouds are composed primarily of ice crystals, while low clouds are composed primarily of water droplets. This difference is most likely because the average air temperature at altitudes from: 1.0 km to 3.2 km is at or below 0°C, while the average air temperature at altitudes from 3.2 km to 6.0 km is above 0°C. 2.0 km to 3.2 km is at or below 0°C, while the average air temperature at altitudes from 6.0 km to 16.0 km is above 0°C. 3.0 km to 3.2 km is above 0°C, while the average air temperature at altitudes from 3.2 km to 6.0 km is at or below 0°C. 4.0 km to 3.2 km is above 0°C, while the average air temperature at altitudes from 6.0 km to 16.0 km is at or below 0°C. Passage 3 Questions 29

31 17. High clouds are composed primarily of ice crystals, while low clouds are composed primarily of water droplets. This difference is most likely because the average air temperature at altitudes from: 1.0 km to 3.2 km is at or below 0°C, while the average air temperature at altitudes from 3.2 km to 6.0 km is above 0°C. 2.0 km to 3.2 km is at or below 0°C, while the average air temperature at altitudes from 6.0 km to 16.0 km is above 0°C. 3.0 km to 3.2 km is above 0°C, while the average air temperature at altitudes from 3.2 km to 6.0 km is at or below 0°C. 4.0 km to 3.2 km is above 0°C, while the average air temperature at altitudes from 6.0 km to 16.0 km is at or below 0°C. Passage 3 Questions 30 Cloud cover is the percent of Earth’s surface covered by clouds. Cloud cover may increase because of an increase in the cosmic ray flux (number of high-energy particles from space reaching Earth per m 2 per hour). Table 1 shows how Earth’s cover of low clouds (0 km to 3.2 km altitude) varies with the cosmic ray flux. Figures 1−3 show the relative cosmic ray flux, RCRF (the percent below the flux measured on October 1, 1965), and the monthly aver-age cover of high clouds (6.0 km to 16.0 km altitude), middle clouds (3.2 km to 6.0 km altitude), and low clouds, respectively, from January 1980 to January 1995.

32 17. High clouds are composed primarily of ice crystals, while low clouds are composed primarily of water droplets. This difference is most likely because the average air temperature at altitudes from: 1.0 km to 3.2 km is at or below 0°C, while the average air temperature at altitudes from 3.2 km to 6.0 km is above 0°C. 2.0 km to 3.2 km is at or below 0°C, while the average air temperature at altitudes from 6.0 km to 16.0 km is above 0°C. 3.0 km to 3.2 km is above 0°C, while the average air temperature at altitudes from 3.2 km to 6.0 km is at or below 0°C. 4.0 km to 3.2 km is above 0°C, while the average air temperature at altitudes from 6.0 km to 16.0 km is at or below 0°C. Passage 3 Questions 31 Cloud cover is the percent of Earth’s surface covered by clouds. Cloud cover may increase because of an increase in the cosmic ray flux (number of high-energy particles from space reaching Earth per m 2 per hour). Table 1 shows how Earth’s cover of low clouds (0 km to 3.2 km altitude) varies with the cosmic ray flux. Figures 1−3 show the relative cosmic ray flux, RCRF (the percent below the flux measured on October 1, 1965), and the monthly aver-age cover of high clouds (6.0 km to 16.0 km altitude), middle clouds (3.2 km to 6.0 km altitude), and low clouds, respectively, from January 1980 to January 1995.

33 17. High clouds are composed primarily of ice crystals, while low clouds are composed primarily of water droplets. This difference is most likely because the average air temperature at altitudes from: 1.0 km to 3.2 km is at or below 0°C, while the average air temperature at altitudes from 3.2 km to 6.0 km is above 0°C. 2.0 km to 3.2 km is at or below 0°C, while the average air temperature at altitudes from 6.0 km to 16.0 km is above 0°C. 3.0 km to 3.2 km is above 0°C, while the average air temperature at altitudes from 3.2 km to 6.0 km is at or below 0°C. 4.0 km to 3.2 km is above 0°C, while the average air temperature at altitudes from 6.0 km to 16.0 km is at or below 0°C. Passage 3 Questions 32 Cloud cover is the percent of Earth’s surface covered by clouds. Cloud cover may increase because of an increase in the cosmic ray flux (number of high-energy particles from space reaching Earth per m 2 per hour). Table 1 shows how Earth’s cover of low clouds (0 km to 3.2 km altitude) varies with the cosmic ray flux. Figures 1−3 show the relative cosmic ray flux, RCRF (the percent below the flux measured on October 1, 1965), and the monthly aver-age cover of high clouds (6.0 km to 16.0 km altitude), middle clouds (3.2 km to 6.0 km altitude), and low clouds, respectively, from January 1980 to January 1995.

34 17. High clouds are composed primarily of ice crystals, while low clouds are composed primarily of water droplets. This difference is most likely because the average air temperature at altitudes from: 1.0 km to 3.2 km is at or below 0°C, while the average air temperature at altitudes from 3.2 km to 6.0 km is above 0°C. 2.0 km to 3.2 km is at or below 0°C, while the average air temperature at altitudes from 6.0 km to 16.0 km is above 0°C. 3.0 km to 3.2 km is above 0°C, while the average air temperature at altitudes from 3.2 km to 6.0 km is at or below 0°C. 4.0 km to 3.2 km is above 0°C, while the average air temperature at altitudes from 6.0 km to 16.0 km is at or below 0°C. Passage 3 Questions 33 Cloud cover is the percent of Earth’s surface covered by clouds. Cloud cover may increase because of an increase in the cosmic ray flux (number of high-energy particles from space reaching Earth per m 2 per hour). Table 1 shows how Earth’s cover of low clouds (0 km to 3.2 km altitude) varies with the cosmic ray flux. Figures 1−3 show the relative cosmic ray flux, RCRF (the percent below the flux measured on October 1, 1965), and the monthly aver-age cover of high clouds (6.0 km to 16.0 km altitude), middle clouds (3.2 km to 6.0 km altitude), and low clouds, respectively, from January 1980 to January 1995.

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