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CHAPTER 8—EARLIEST EARTH: 2,100,000,000 YEARS OF THE ARCHEAN EON CHAPTER OVERVIEW This chapter opens with a short presentation of basic astronomy to place Earth in context with the rest of the Universe. Our solar system is a small part of a much larger aggregate of stars, planets, dust, and gases called a galaxy. Our galaxy, the Milky Way, contains the sun and the nine planets that orbit around it. The most widely proposed theories of the origin of the universe must conform to an important astronomical observation called the “red shift.” The red shift theory is examined along with the big bang, steady-state cosmology, and oscillating universe cosmology theories. The development of the solar system is attributed to the nebular hypothesis, which is explained in detail and verified by meteorites found on Earth. This is followed by a solar system tour from center to fringe explaining the composition and atmosphere of the nine planets. After the comprehensive detailed review of the solar system, the differentiation of Earth is discussed followed by an explanation of the development of the atmosphere and the “hydrologic” cycle. The structural features of the Archean, shields, platforms, and cratons, along with the two major rock associations, granulites and greenstones, are discussed in terms of their relationship to plate tectonics. The chapter concludes with a detailed discussion of the origin of life on Earth. This includes the role of the Earth’s mid-oceanic ridges and the ocean itself in this process. The earliest life forms of “The First Two Billion Years” are described, noting the associations of the anaerobic, aerobic, prokaryotes, eukaryotes, heterotrophs, autotrophs, and the fossil record left by these earliest forms. The Archean was the eon when basic mechanisms governing geologic change were established and it was the time when life appeared. LEARNING OBJECTIVES By reading and completing information within this chapter, you should gain an understanding of the following concepts: Discuss the theories of the origin of the universe, solar system, and planet Earth. Explain the astronomical observation of the red shift in explaining the origin of the universe. Describe the role of meteorites in the formation of the Earth and the other planets. Briefly compare the composition of the nine planets and their atmospheres. Discuss how the Earth became differentiated into three distinct layers: the core, the mantle, and the crust. Discuss the evolution of the Earth’s atmosphere and the development of the “hydrologic” cycle. Define the dominant structural features of the Archean Eon: shields, cratons, and platforms and how they relate to plate tectonics. Locate the major Pre-Cambrian shield areas on a map: Canadian shield, Baltic shield, Patagonian shield, etc. Discuss the formation of the two major rock associations known as granulites and greenstones. Describe characteristics that separate life forms of the Archean: anaerobic, aerobic, prokaryotes, eukaryotes, heterotrophs and autotrophs. Describe the fossil record of the Archean and the importance of stromatolites. Explain what molecular fossils are and describe where they have been found. CHAPTER OUTLINE I. Earth in Context: a Little Astronomy A. The Solar Nebula Hypothesis B. Meteorites: Samples of the Early Solar System Chapter 8—Earliest Earth: 2,100,000,000 Years of the Archean Eon II. A Solar System Tour A. The Sun 1. Distance from the Sun 2. Earth’s Rotation 3. Earth’s Atmosphere B. The Four Inner Planets 1. Mercury: Hot, Pockmarked and Swift 2. Venus: Nothing We Know Could Survive Here 3. Earth: The Best of All Possible Worlds 4. Earth’s Moon 5. Mars: Once Wetter, Warmer and Host to Life 6. The Asteroid Belt C. The Five Outer Planets 1. Jupiter and Saturn: Giant Gas Balls 2. Uranus and Neptune: The Twin Planets 3. Pluto: An Outlier III. Following Accretion, Earth Differentiates A. The Archean Crust IV. The Primitive Atmosphere A. Growing an Oxygen-Rich Atmosphere B. Geologic Clues to Early Atmosphere V. The Primitive Ocean and the Hydrologic Cycle VI. Origin of Precambrian “Basement” Rocks A. Where Can We See Precambrian Rocks B. Continental Crust Appears Worldwide C. The Earliest Plate Tectonics 1. Granulites and Greenstones 2. Archean Sedimentation VII. The Origin of Life A. How Molecules Might Combine to Start Life B. Pulling Together the Pieces of Life C. Simulating the Origin of Life D. Where Did Life Begin E. Hyperthermophiles and Chemosynthesis F. Life in Extremely Hostile Environments G. Feeding Life on Earth H. Prokaryotes and Eukaryotes I. Archean Fossils J. Molecular Fossils VIII. In Retrospect Chapter 8—Earliest Earth: 2,100,000,000 Years of the Archean Eon KEY TERMS (Pages 207–241) accretion (210): In the development of protoplanets, the process of accumulation of bits of matter around an initial mass. aerobic organism (235): An organism that uses oxygen in carrying out respiratory processes. anaerobic organism (235): An organism that does not require oxygen for respiration, but rather makes use of processes such as fermentation to obtain its energy. anorthosite (226): These intrusive gabbroic rocks are associated with tonalities, granodiorites, and granites that form the granulite association. Archean Eon (224): Division of the Precambrian time from 3800 million years to 2500 million years ago. Origin of life began in the eon. autotroph (234): An organism that uses an external source of energy to produce organic nutrients from simple inorganic chemicals. banded iron formation (BIF) (223): A rock that consists of alternating bands of iron-rich minerals, generally hematite, and chert or fine-grained quartz. Canadian shield (225): The most extensive exposure of Precambrian rocks in North America. This geologically stable region extends across 3 million square miles. carbonaceous chondrite (211): Meteorites that take their name from spherical bodies called chondrites which contain nitrogen, hydrogen, carbon, dark iron, and magnesium silicates and water. chemosynthesis (232): A means by which organisms derive their energy by oxidizing such inorganic substances as hydrogen sulfide or ammonia. chondrules (211): Spherical bodies that are solidified molten droplets splashed into space during an impact that are found in chondrites. craton (225): The long-stable region of a continent, commonly with Precambrian rocks either at the surface or only thinly covered with younger sedimentary rocks. differentiation (planetary) (219): The process by which a planet becomes internally zoned, as when heavy materials sink toward its center and light materials accumulate near the surface. eukaryote (235): A type of living cell containing a true nucleus, enclosed within a nuclear membrane, and having well-defined chromosomes and cell organelles. felsic (225): Meaning rich in feldspars, quartz, and muscovite, as the continental crust. fermenter (234): The partial breakdown of organic compounds by an organism in the absence of oxygen. The final product of fermentation is alcohol or lactic acid. fusion (210): The molten state of a substance, or the change it undergoes to become molten. granulite (226): A major rock association of the Archean cratons. Composed largely of gneisses derived from strongly heated and deformed tonalities, granodiorites, and granites, as well as layered intrusive gabbroic rocks called anorthosites. greenstone (228): A major rock association of the Archean cratons. Usually occur in roughly trough-like or synclinal belts. Prominent features of Archean terrains of all continents. Composed of basaltic, andesitic, and rhyolitic volcanic rocks along with metamorphosed sediments derived by weathering and derosion of the volcanics. Lavas of greenstone belts exhibit pillow structures that indicate that they were extruded under water. Chapter 8—Earliest Earth: 2,100,000,000 Years of the Archean Eon heterotroph (235): An organism that depends on an external source of organic substances for its nutrition and energy. hydrologic cycle (224): The continuous recirculation of water by evaporation and precipitation— processes powered by the sun and gravity. hyperthermophile (232): Literally, high-heat lovers. iron meteorite (212): Iron nickel. Asteroids are the probable source for iron meteorites. komatiite (221): Ultramafic rocks that solidified from surface patches when the magma ocean cooled. Formed at temperatures greater than 1100 degrees Centigrade, required to produce basalt. They reflect the higher temperature gradients that prevailed during the late Hadean. lithotroph (234): Subterranean microbes that have been dubbed “rock nourishment.” Most lithotrophs live off energy derived from hydrogen, iron, magnesium, and sulfur. lunar highlands (215): The lighter-hued craggy and heavily cratered regions of the moon. mafic (225): Rocks (or lava) dominated by dark iron and magnesium silicates as is the oceanic crust. magma ocean (220): The melting of the upper mantle during the early Archean infancy that may have covered Earth’s surface. maria (215): The darker areas of the moon. These darker areas form the floors of immense basins that have been flooded with dark basaltic lava. (singular = mare) meterorite (210): Meteors that survive the heat and reach the Earth’s surface. molecular fossils (239): Preserved organic molecules that only eukaryotes can synthesize. nebular hypothesis (209): The idea first suggested by German philosopher Immanuel Kant in 1755, proposes that the solar system distilled from a rotating cloud of dust particles and gases called the solar nebula. ordinary chondrites (211): One of four meteorite compositions and are most abundant and at 4.6 billion years old, are clearly Archean in age. Chondrites contain spherical bodies called chondrules that are solidified molten droplets splashed into space during an impact. organelles (230): Bodies capable of performing specific function. outgassing (222): The process by which water vapor and other gases are released from the rocks that held them and then vented to the surface. partial melting (220): The variation in melting that occurs in different minerals in an original rock mass. photoautotroph (235): Organisms that were capable of carrying on photosynthesis, the unique capability of dissociating carbon dioxide into carbon and free oxygen. photochemical dissociation (222): The process of water molecules into hydrogen and oxygen. The process occurs in the upper atmosphere when water molecules are split by high-energy beams of ultraviolet light from the sun. photosynthesis (223): The process of synthesizing carbohydrates from carbon dioxide and water, utilizing the radiant energy of light captured by the chlorophyll in plant cells. platform (225): That part of a craton covered thinly by layered sedimentary rocks and characterized by relatively stable tectonic conditions. Precambrian (224): Term used to describe rocks that were older than the Cambrian Period Chapter 8—Earliest Earth: 2,100,000,000 Years of the Archean Eon Precambrian provinces (225): Divisions of the Canadian shield based on differences in the trends of faults and folds, the style of folding, and the ages of component rocks. prokaryote (235): Organisms that lack membrane-bounded nuclei and other membrane-bounded organelles. Proterozoic Eon (224): A younger divide of Precambrian time used to describe rocks. protoplanet (210): Large globules formed from swarms of accreting bodies, dust, and gases. Enormously larger than present-day planets. Each rotated somewhat like a miniature dust cloud, and each eventually swept away most of the debris in its orbital path and was able to revolve around the central mass without collision with other protoplanets. Formation required an estimated 10 million years. shield (Precambrian) (225): Broadly upwarped, geologically stable regions of continents. Every continent has one or more shields. The Canadian shield extends across 3 million square miles of northern North America. solar nebula (209): The rotating cloud of dust particles and gases from which the solar system was derived. solar system (208): In one galaxy of many located in the universe contains the Milky Way. Among the Milky Way’s billions of stars is a small one, our sun. Around the sun swirl nine planets, thousands of asteroids and comets, and countless bits of space debris that comprise the solar system. solar wind (210): The stream of radiation from the sun, which drove enormous quantities of lighter elements and frozen gases outward into space. This solar force is what causes a comet’s tail to show wavy streaming or to be bent away from the sun. Also, this is the reason the planets closest to the sun have smaller masses, but greater densities than the outer planets. stony-iron meteorite (212): The least abundant of the meteorites. Derived from a shattered asteroid, originating from the area in the asteroid that lies between the iron core and the surrounding rocky shell. They are composed of silicate minerals and iron nickel. stromatolite (236): Distinctly laminated accumulations of calcium carbonate having rounded, branching, or frondose shape and believed to form as a result of the metabolic activity of marine algae. They are usually found in the high intertidal to low supratidal zones. Associated with Cyanobacteria. ultramafic (228): Rock or lava with extremely high concentrations of iron and magnesium. Chapter 8—Earliest Earth: 2,100,000,000 Years of the Archean Eon MULTIPLE-CHOICE QUESTIONS 1. Theories for the origin of the universe must conform to an important astronomical observation called a. oscillating universe cosmology. c. solar nebula. b. big bang. d. red shift. 2. The process occurring in the upper atmosphere by which water molecules are split by high-energy beams of ultraviolet light from the sun is termed a. photochemical dissociation. c. photoautotrophy. b. photosynthesis. d. outgassing. 3. The process by which water vapor and other gases were released from rocks within the first billion years of Earth’s history. a. sublimation c. outgassing b. photosynthesis d. photochemical dissociation 4. When early geologists first began to describe local sequences of strata, they sometimes encountered a primary or basement complex of metamorphic and igneous rocks that lay beneath fossil-bearing sedimentary strata. The older more crystalline rocks came to be known as a. Hadean. c. Early Archean. b. Proterozoic. d. Precambrian. 5. The most extensive exposures of Precambrian rocks are in geologically stable regions of continents called a. cratons. c. Precambrian provinces. b. platforms. d. shields. 6. Relatively thin blankets of sedimentary strata that cover regions of stable, basement rocks is called a a. craton. c. Precambrian province. b. platform. d. shield. 7. The Canadian shield is divided into several provinces on the basis of a. fossil content. b. structural trends and age dates. c. the composition of the basement rocks. d. sedimentary structures such as cross-bedding and paleocurrent directions. 8. The Precambrian is ordered, from oldest to youngest, into the a. Archean, Hadean, and Proterozoic Eons. c. Hadean, Archean, and Proterozoic Eons. b. Proterozoic, Hadean, and Archean Eons. d. Proterozoic, Archean, and Hadean Eons. 9. The upper most units of a greenstone sequence consist mostly of a. mafic volcanic rocks. c. marine sedimentary rocks. b. felsic volcanic rocks. d. terrestrial sedimentary rocks. 10. Pillow lavas found in greenstone belts suggest a. subaqueous eruptions. c. intrusive feeder dikes from a nearby volcano. b. ash flow deposits. d. higher temperatures for the basalt being extruded. 11. Granulites are a. sedimentary rocks composed of poorly sorted and angular igneous rock fragments. b. metamorphic rocks formed from felsic igneous rocks by structural deformation and high temperatures. c. igneous rocks formed entirely of plagioclase feldspar. d. metamorphic rocks formed from obducted oceanic crust. Chapter 8—Earliest Earth: 2,100,000,000 Years of the Archean Eon 12. The uppermost units of greenstone belts consist mainly of a. ultramafic rocks. c. sedimentary rocks. b. basaltic rocks. d. metamorphic rocks. 13. Stanley Miller and Harold Urey, in 1953, circulated methane, ammonia, and hydrogen in an apparatus recreating the Archean atmosphere. By supplying an electrical current they produced a. amino acids. c. ribonucleic acids. b. nucleic acids. d. hydrocarbons. 14. Organisms that manufacture their own food from simple inorganic substances are called a. fermenters. c. heterotrophs. b. bacteria. d. autotrophs. 15. The process whereby organisms release free oxygen (as a waste product) into the atmosphere is called a. respiration. c. photosynthesis. b. photochemical dissociation. d. fermentation. 16. An organism that can live in an oxygen-rich environment is called a. aerobic. c. planktonic. b. anaerobic. d. photosynthetic. 17. An organism that uses an external source of energy to produce organic nutrients from simple inorganic chemicals is a/an a. aerobic. c. autotroph. b. mitochondria. d. prokaryote. 18. The province of eastern Canada that is the youngest, middle proterozoic region of the Canadian shield and the last to experience a major orogeny is a. Ontario. c. Superior. b. Grenville. d. Labrador. 19. These organisms reproduce sexually, with a union of egg and sperm to form the nucleus of a single cell. a. lithotrophs c. autotrophs b. eukaryotes d. heterotrophs 20. The granulite association which is composed largely of gneisses derived from deformed granitic rocks, as well as more gabbroic rocks is called a. komatiites. d. rhyolites. b. anorthosites. e. graywackes. c. andesites. Chapter 8—Earliest Earth: 2,100,000,000 Years of the Archean Eon FILL IN THE BLANK 1. These stable regions where basement rocks are covered by relatively thin blankets of sedimentary strata are called . 2. The term used for the continental crust that is rich in feldspar, quartz, and muscovite is called crust. 3. The ultramafic rocks that reflect the higher temperature gradients that prevailed during the Hadean are called . 4. A mountain-building event that occurred in the late-Archeon Eon in Canada that created high temperatures that melted rocks at depth and emplaced a gigantic batholite is called . 5. The theory concerning the origin of the universe that indicates that the universe is expanding is . 6. The Archean rock association that is composed largely of gneisses derived from strongly-heated and deformed tonalites, granodiorites and granites is 7. The Archean rock association in which felsic volcanics occur above mafic rocks which are overlain by shales, graywackes, conglomerates and banded iron formations, is called . 8. Gneisses and layered intrusive gabbroic rocks form the Archean rock association are called: . 9. The belt structures believed to be the remnants of a once highly-active volcanic trough or synclinal belt are called . 10. An organism that uses an external source of energy to produce organic nutrients from simple inorganic compounds is called a/an . 11. The type of prokaryote that produces its own food by the processes of photosynthesis and asexual reproduction is called . 12. The early organisms that had a definite nuclear wall, well-defined chromosomes, and the capacity for sexual reproduction are called . 13. The laminar, organic sedimentary structures formed by the trapping of sedimentary particles and precipitation of calcium carbonate in response to the metabolic activities and growth of mat-like colonies are called . 14. The idea that the solar system originated as a result of distilling from a rotating cloud of dust particles is called the _____________ ______________. 15. Modern Earth is a differentiated planet that has three very distinct layers: _____________, ____________, and _______________. . Chapter 8—Earliest Earth: 2,100,000,000 Years of the Archean Eon TRUE/FALSE 1. The “Big Bang” occurred between 3-5 billion years ago and marked the creation of the solar system. 2. The oscillating universe cosmology proposes that for every big bang there is a big crunch. 3. Theories for the origin of the universe must conform to the red shift. 4. Banded iron formations that show alterations of rusty-red and gray bands indicate abundant free oxygen in the environment. 5. Komatiites are ultramafic rocks that reflect the higher-temperature gradients that prevailed during the Hadean. 6. Prokaryotes were organisms with a definite nuclear wall, well-defined chromosomes, and the capacity for sexual reproduction. 7. The process of accumulating bits of matter around an initial mass is called accretion. 8. The darker areas that are seen on the moon are called lunar highlands. 9. Photochemical dissociation is the process by which water vapor and other gases are released from rocks. 10. Autotrophs can’t make their own food so they scavenge nutrients in their environment. Chapter 8—Earliest Earth: 2,100,000,000 Years of the Archean Eon ANSWER KEY Multiple Choice 1. d 2. a 3. c 4. d 5. d 6. b 7. b 8. c 9. c 10. a 11. b 12. c 13. a 14. d 15. c 16. a 17. c 18. b 19. b 20. b Fill Ins 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. platforms felsic Komatiites Kenoran Orogeny red shift granulite association greenstone association granulite association greenstone belt autotroph cyanobacteria eukaryote stromatolite nebular hypothesis core, mantel, crust True/False 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. F T T T T F F F F F Chapter 8—Earliest Earth: 2,100,000,000 Years of the Archean Eon RESPONSES TO QUESTIONS ACCOMPANYING SELECTED FIGURES FIGURE 8–3 (p. 209) From above, the Milky Way galaxy would resemble a discoidal spiral consisting of stars, planets, satellites, meteors, comets, gases, and dust. FIGURE 8–12 (p. 216) Escaping gases were responsible for the spherical holes in the lunar basalt. This indicates a relative, rapid cooling of this rock. FIGURE 8–27 (p. 227) Both shield and platform are components of the craton. Platforms are regions of the craton in which igneous and metamorphic basement rocks are covered by a blanket of sedimentary rocks.