Life in the Universe (4th Edition)
4th Edition
ISBN: 9780134089089
Author: Jeffrey O. Bennett, Seth Shostak
Publisher: PEARSON
expand_more
expand_more
format_list_bulleted
Textbook Question
Chapter 8, Problem 18RQ
What do we mean by terraforming Mars? Is it something we could do within our lifetimes?
Expert Solution & Answer
Want to see the full answer?
Check out a sample textbook solutionStudents have asked these similar questions
where do you think we should establish a colony first? In Mars or in Moon?
CO2 and planetary warming: understanding Earth’s complicated atmosphere Mars has an atmospheric pressure of 6 mbar (compared with Earth atmosphere pressure of 1013 mbar), 96% of which is CO2. The average calculated temperature of Mars is -57°C, whereas the actual average temperature is -55°C so that the amount of warming due to CO2 is only 2°C. On the other hand, the average calculated temperature of Earth, with 0.4 mbar of CO2, is -19°C, whereas the actual average temperature is 15°C so that the amount of warming due to CO2 is 34°C, much greater than that on Mars, which has higher CO2 concentration. Explain how this is possible.
For which of the following reasons (select all that apply), is it useful/important to send rovers to other planetary bodies in our solar system?
O a. The engineering innovations developed to produce successful/viable rovers and landers on other planets can help lead to developments in the technology used here on Earth that may have taken far more time to develop without the limitations provided by space travel
to foreign worlds.
O b. The data collected can help improve our understanding of the evolution/development of our solar system.
O. Rovers/landers can be outfitted with various tools and equipment that can be used to inform of us of the geological histories of each of the planets they visit.
O d. More direct probes of the planetary surface are possible to detect signs of the building blocks of life.
O e. Rock samples can be used to calibrate our estimations of the age of the solar system.
Chapter 8 Solutions
Life in the Universe (4th Edition)
Ch. 8 - Briefly summarize the evidence, both real and...Ch. 8 - What would it be like to walk on Mars today?...Ch. 8 - Why isnt liquid water stable at the martian...Ch. 8 - How do martian seasons differ from Earth seasons?...Ch. 8 - Give a brief overview of the geography and major...Ch. 8 - How do we know that different regions of the...Ch. 8 - Summarize the evidence suggesting that Mars must...Ch. 8 - What evidence suggests that water might still flow...Ch. 8 - Why do we conclude that Mars must once have had a...Ch. 8 - What is the leading hypothesis concerning how Mars...
Ch. 8 - How and why does Marss axis tilt change with time,...Ch. 8 - Based on all the geographic and geological...Ch. 8 - Briefly summarize the Viking experiments and their...Ch. 8 - What is the potential significance of atmospheric...Ch. 8 - Briefly summarize plans for Mars exploration over...Ch. 8 - Discuss the issue of biological contamination in...Ch. 8 - Summarize the scientific pros and cons of sending...Ch. 8 - What do we mean by terraforming Mars? Is it...Ch. 8 - How do we know that ALH84001 really came from...Ch. 8 - Briefly summarize the possible evidence of past...Ch. 8 - The first human explorers on Mars discover that...Ch. 8 - We discover a string of active volcanoes in the...Ch. 8 - We find underground pools of water on the slopes...Ch. 8 - We discover that Mars was subjected to global,...Ch. 8 - A future orbiter finds a plume of volcanic gas...Ch. 8 - We find a lake of liquid water filling a small...Ch. 8 - The first fossils discovered on Mars come from the...Ch. 8 - A sample return mission finds fossil evidence not...Ch. 8 - We discover that the martian polar caps have in...Ch. 8 - We find rocks on Mars showing clearly that the...Ch. 8 - When we say that liquid water is unstable on Mars,...Ch. 8 - Marss seasonal winds are driven primarily by (a)...Ch. 8 - Olympus Mons is (a) a giant volcano; (b) a huge...Ch. 8 - We can recognize the oldest surface regions of...Ch. 8 - Minerals in surface rock studied by the martian...Ch. 8 - Rivers on Mars (a) have never existed; (b) existed...Ch. 8 - Which must be true if Mars was warmer and wetter...Ch. 8 - Which of the following fundamental properties of...Ch. 8 - According to the leading hypothesis, if Mars once...Ch. 8 - The Viking experiments found (a) no evidence of...Ch. 8 - The Role of the Martians. Percival Lowell may have...Ch. 8 - Learning from Past Mistakes. The Viking missions...Ch. 8 - Hold Your Breath. If you held your breath, would...Ch. 8 - Miniature Mars. Suppose Mars were significantly...Ch. 8 - Larger Mars. Suppose Mars were significantly...Ch. 8 - Civilization on Mars. Based on what we can see on...Ch. 8 - Martian Fossil Hunting. On Earth, we cannot find...Ch. 8 - Future Landing Site. Suppose you were in charge of...Ch. 8 - Terraforming Mars. Make a list of the pros and...Ch. 8 - Mars Movie Review. Watch one of the many science...Ch. 8 - Interior Heat. Compare the surface areatovolume...Ch. 8 - Atmospheric Mass of Earth. What is the total mass...Ch. 8 - Atmospheric Mass of Mars. The weaker gravity of...Ch. 8 - Past Gas on Mars. Models suggest that Mars today...Ch. 8 - Lessons from Mars. Discuss the nature of the...Ch. 8 - Human Exploration of Mars. Should we send humans...Ch. 8 - Current Mars Missions. Pick one of the Mars...Ch. 8 - Future Mars Missions. Pick one of the Mars...
Additional Science Textbook Solutions
Find more solutions based on key concepts
10.38 (a) Calculate the magnitude of the angular momentum the earth in a circular orbit around the sun. Is it r...
University Physics (14th Edition)
26. A 10 kg crate is placed on a horizontal conveyor belt. The materials are such that and .
a. Draw a free-...
Physics for Scientists and Engineers: A Strategic Approach, Vol. 1 (Chs 1-21) (4th Edition)
By holding a magnifying glass 25 cm from your desk lamp, you can focus an image of the lamps bulb on a wall 1.6...
Essential University Physics: Volume 2 (3rd Edition)
The speed of the person sitting on the chair relative to the chair and relative to Earth.
Conceptual Physics (12th Edition)
If the angle between the two verticals extended to Earths center Figure1.4 were 10o instead 7.2o, still subtend...
Conceptual Integrated Science
56. A 25 kg child bounces on a pogo stick. The pogo stick has a spring with spring constant 2.0 × 104 N/m. When...
College Physics: A Strategic Approach (3rd Edition)
Knowledge Booster
Learn more about
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, physics and related others by exploring similar questions and additional content below.Similar questions
- Impact Energy. Consider a comet about 2 kilometers across with a mass of 4 × 1012 kg. Assume that it crashes into Earth at a speed of 30,000 meters per second (about 67,000 miles per hour). a. What is the total energy of the impact, in joules? (Hint: The kinetic energy formula tells us that the impact energy in joules will be 1 × m × v2, where 2 m is the comet’s mass in kilograms and v is its speed in meters per second.) b. A 1-megaton nuclear explosion releases about 4 × 1015 joules of energy. How many such nuclear bombs would it take to release as much energy as the comet impact? c. Based on your answers, comment on the degree of devastation the comet might cause.arrow_forwardUsing the GUFSA Template. Round off your final answer to the nearest hundredths. As we already know, rockets travel at very high speeds. How much time will it take a rocket (in seconds) to reach the moon if the moon is 238,900 miles away from the Earth, and the rocket is travelling 1,800,000 centimeters per minute? (express your answer in meters per second)arrow_forwardThe gravity on Mars is about 38% that of Earth's gravity. Let's say some cargo has a mass of 15 kg here on Earth. First, what would be the weight of that cargo in kilograms on Mars? Explain your answer. Second, what would be the mass of that cargo in kilograms on Mars? Explain your answer.arrow_forward
- Please help me with this question. A=.2arrow_forwardIf we send astronauts to Mars, there will be a time delay anytime we send or receive messages to them here on Earth. Given that Mars is an average of 54.6 million km away from Earth, how long is this time delay for a 2-way 'round-trip' communication - sent to Earth, then back to Mars? (this might be important in emergency situations) answer choices a)About 4 minutes. b)About 30 seconds. c)About 10 seconds. d)About 6 minutes.arrow_forwardActivity #1. Compare and Contrast. Similarities and differences of Venus, Earth and Mars. Do this on a separate sheet of paper. 1. Compare and contrast the three (3) terrestrial planets using table 1. 2. Provide explanations for your observations using table 2. 3. Answer the following guide questions. Guide questions: 1. Does planet size affect gravity? 2. Why do you think Venus has the highest mean temperature among the three planets? 3. Is presence of water a primary factor for a planet to sustain life? Why or why not? 4. Based on your observations using table 2, what are the notable features that makes the earth the only habitable planet among the three terrestrial planets? 5. What conclusions can you make?arrow_forward
- Which of the following is least reasonable regarding the concept of a habitable zone? Group of answer choices M-type stars have wider habitable zones than G-type stars. It is a region around a star where liquid water could be found on a planet's surface. The habitable zone of a less massive star would be closer to the star. In the course of millions of years, our habitable zone will slowly shift from Earth to Mars. The Galactic habitable zone cannot be too close to the Galactic center because the radiation from the bright stars and supernovae in the crowded inner part of the Galaxy would probably be detrimental to life.arrow_forwardTutorial A radio broadcast left Earth in 1923. How far in light years has it traveled? If there is, on average, 1 star system per 400 cubic light years, how many star systems has this broadcast reached? Assume that the fraction of these star systems that have planets is 0.50 and that, in a given planetary system, the average number of planets that have orbited in the habitable zone for 4 billion years is 0.40. How many possible planets with life could have heard this signal? Part 1 of 3 To figure out how many light years a signal has traveled we need to know how long since the signal left Earth. If the signal left in 1923, distance in light years = time since broadcast left Earth. d = tnow - broadcast d = 97 97 light years Part 2 of 3 Since the radio signal travels in all directions, it expanded as a sphere with a radius equal to the distance it has traveled so far. To determine the number of star systems this signal has reached, we need to determine the volume of that sphere. V, = Vb…arrow_forwardTutorial A radio broadcast left Earth in 1925. How far in light years has it traveled? If there is, on average, 1 star system per 400 cubic light years, how many star systems has this broadcast reached? Assume that the fraction of these star systems that have planets is 0.30 and that, in a given planetary system, the average number of planets that have orbited in the habitable zone for 4 billion years is 0.85. How many possible planets with life could have heard this signal? Part 1 of 3 To figure out how many light years a signal has traveled we need to know how long since the signal left Earth. If the signal left in 1925, distance in light years = time since broadcast left Earth. d = tnow - tbroadcast d = light years Submit Skip (you cannot come back)arrow_forward
- How is a habitable zone likely to change over time? a. get narrower b. move further from the star c. they aren't likely to changearrow_forwardFigure 9 shows photos of Mars taken by the Hubble Space Telescope during the planet’s spring and summer seasons. Briefly describe the changes you notice on the planet’s surface. How do these changes compare to the seasonal changes on Earth?arrow_forwardOut of the inner planets in the solar system (Mercury, Venus and Mar) which do you think is the most likely to be colonized? Explain why?arrow_forward
arrow_back_ios
SEE MORE QUESTIONS
arrow_forward_ios
Recommended textbooks for you
- AstronomyPhysicsISBN:9781938168284Author:Andrew Fraknoi; David Morrison; Sidney C. WolffPublisher:OpenStaxFoundations of Astronomy (MindTap Course List)PhysicsISBN:9781337399920Author:Michael A. Seeds, Dana BackmanPublisher:Cengage Learning
- Stars and Galaxies (MindTap Course List)PhysicsISBN:9781337399944Author:Michael A. SeedsPublisher:Cengage Learning
Astronomy
Physics
ISBN:9781938168284
Author:Andrew Fraknoi; David Morrison; Sidney C. Wolff
Publisher:OpenStax
Foundations of Astronomy (MindTap Course List)
Physics
ISBN:9781337399920
Author:Michael A. Seeds, Dana Backman
Publisher:Cengage Learning
Stars and Galaxies (MindTap Course List)
Physics
ISBN:9781337399944
Author:Michael A. Seeds
Publisher:Cengage Learning
Kepler's Three Laws Explained; Author: PhysicsHigh;https://www.youtube.com/watch?v=kyR6EO_RMKE;License: Standard YouTube License, CC-BY