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Homework Problem Set, Week 2. Due Friday, January 22: Please show your calculations. Name________________________ 1. The total amount of carbon on the earth’s surface depends on a balance between the input of new carbon – from the CO2 derived from volcanism at mid-ocean ridge spreading centers, and the sink of carbon-rich sediments being carried back down into the earth’s mantle at subduction zones. Most variations in global climate are determined by the partitioning of this carbon into the various reservoirs on the earth’s surface (air, oceans, sediments, biology), and there is a general balance between input of new carbon and burial in the deep mantle of old carbon. 1a. Assume that the total length of all seafloor spreading centers (globally) is 59,200 km and that the average spreading rate is 55.7 ± 3.4 mm/year. Also assume that oceanic crust is about 6 km thick, with the Upper Crust is made up of a 1 km thickness of extrusive (volcanic) basalts and upper feeder dikes, and the Lower Crust is a 5 km thick layer of lower dikes and gabbros (a frozen magma chamber). Calculate the total volume of oceanic crust produced each year (including both upper and lower crust) in km3/year. 1b. Assume the Upper and Lower Crust has a density of 3.0 gm/cm3. Upper Oceanic Crust (the basalts and upper dikes) are about 0.04 % CO2 by weight. Assume that all of the CO2 in the Upper Crust is removed immediately after formation (relative to the spreading rate) – the gas is ejected by the rocks as they solidify and carried by hydrothermal circulation into bottom seawater at the ridge axis. Calculate the amount of CO2 (in kilograms/year) that is injected into seawater each year from the formation of Upper Crust. 1c. The Lower Oceanic Crust (the 5 km thickness of lower dikes and gabbros) has a much smaller CO2 content (0.006 % by weight) than the Upper Crust. There is considerable debate if this CO2 is ‘extracted‘ from the lower crust immediately after formation, or is vented in older, off-axis vents. We will assume that it is all vented immediately after formation at the ridge axis for ease of calculation. Compute the total input of CO2 from the formation of lower crust in kg/year. 1d. Total CO2 emitted from crustal formation (under the above assumptions) is (b) plus (c). Assume that the total carbon inventory in the ocean is stable over geological time and the hydrothermal input above is balanced by the transport of carbon-rich sediments into the mantle at subduction zones. The carbon (not CO2) inventory dissolved in seawater is 38 x 10+15 kg. What is the residence time of carbon in the ocean, with respect to seafloor spreading? Assume that all carbon in the ocean starts as CO2 at a spreading ridge. 1e. During the Cretaceous period, when seafloor spreading increased dramatically, the balance between input and burial may have been temporarily tipped in favor of ‘input’. If seafloor spreading increased by a factor of 2.4 times during the early Cretaceous, what would you expect to happen to the rate of seafloor consumption at subduction zones? 1f. Assume that the CO2 emitted by volcanism during seafloor spreading ends up 50% in the oceans (dissolved as carbonate, bicarbonate and dissolved CO2) and 50% in the atmosphere. Describe in the simplest terms how carbon in each of these two reservoirs ends up back in the mantle. 1g. What volcanic and tectonic factors discussed in lecture OTHER than CO2 derived from seafloor spreading volcanism could be responsible for the extreme warmth of the Cretaceous compared to today? 2. At steady state, the rate of CO2 addition to the surface of the earth should be balanced by the rate of removal by weathering of continental rocks and eventual subduction of carbonate rich sediment deposits. In this problem you will estimate the amount of continental rock consumed by chemical weathering from the input of CO2 from seafloor spreading. We will ignore any changes in carbon storage in surface reservoirs (rocks, seawater, air) and assume that all CO2 from seafloor volcanism is consumed by weathering immediately. 2a. The weathering of silicate minerals (the majority of the exposed continents) and their deposition as carbonate minerals is chemically expressed as: (equation 1) CaSiO3+H2O+CO2 CaCO3+SiO2*H2O The molar mass of CaSiO3 (a generic silicate mineral) is 116.16 g/mol. Ignoring anthropogenic impacts and assuming the carbon cycle is at steady state, and further assuming that all weathering and deposition on the modern Earth is of silicate rocks with the above chemical formula, calculate the total mass of silicate consumed by chemical weathering in one year. (HINT: See solution to problem 1b and c) 2b. The increase in atmospheric CO2 during the Cretaceous has been estimated at 3 to 9 times the present pre-industrial concentration. It has also been estimated that the global average temperatures during this period was between 8 and 14°C higher than today. How would these changes have impacted weathering rates as a sink for atmospheric CO2? 2c. Mountain building associated with subduction almost always occurs at the edges of continents (i.e., Andes, Cascades, Aleutian volcanoes). How would an increase in subduction rates in a warmer climate have impacted weathering during the Cretaceous? 3. In the simplest possible form, the radiative balance of the earth (from Problem Set #1) is: (Equation 2) S = σ • T4 Where S is the effective solar insolation (accounting for albedo) of 240 W/m 2, σ is the StefanBoltzman constant [5.67 x 10-8 W/(m2 °K4)] and T is absolute temperature (°K). Underline implies ‘global average value’. An alternative method used for including the impact of Greenhouse gases on earth’s surface temperature modifies Eqn 2 as: (Equation 3) S + G = σ • T4 Where G is the greenhouse gas warming term in units of W/m2. 3a. If the present average temperature at the surface of the earth is now +15°C, calculate the value of G; the amount of heating due to all greenhouse gases in W/m2. 3b. To modify this expression to allow for variations of average global temperature due to changes in CO2 greenhouse gas forcing, we can write Gnew (the new GHG heating) as: (Equation 4) Gnew = G + A • ln [ C / Co ] Where G is the average value calculated above, C is the new concentration of CO2, Co = the preindustrial value of CO2 in the atmosphere of 280 ppm, A (in W/m2) represents the ‘sensitivity’ of greenhouse gas warming to CO2 concentrations, and ln is the natural log. Based on the examination of paleoclimate data, a doubling of CO2 concentrations (2 X 280 ppm) in the past has produced a 2.6°C temperature increase, which is equivalent to A = 20.5 W/m2. Use this information and Eqn 3 to calculate the difference in temperature from present conditions you would expect for the Cretaceous, when the CO2 levels were ~10 times the pre-industrial value. 4. Sea level is roughly proportional to land coverage—as the ocean rises, less land is exposed, and vise versa. The albedo of water is very different than that of continental materials, and changes in the proportion of exposed land mass can alter the effective solar insolation. In this problem you will estimate the impact on global temperature by changing sea-level. 4a. The figure below shows ocean height above the present sea-level. When was sea-level at it’s highest in the Cretaceous, and at what height relative to the present? You will need an accurate answer to finish the problem set, so answer to the nearest 5 m. Sea level vs age 300 Sea Level (meters) 250 200 150 100 50 0 0 20 40 60 80 100 120 140 160 age (My) 4b. What phenomena would have produced the rapid drop in sea level at 30 and 5 My? 4c. The percentage of Earth’s surface that is land can be expressed as: (Equation 5) Po - P = S/25 Where Po is the present percentage of land (30%) and S is the sea-level in meters relative to the present. Using your answer to part a, find the percentage of land. 4d. The table below shows the albedo of a variety of substances. Assume the average albedo of land in the Cretaceous, including rock, clouds, and vegetation, is 30%, and that of water is 10%. Calculate the average global albedo. How does the compare to the modern value of 39.1%, and what two major differences that might cause this? 4d. Using the first equation in the problem set from week 1 and your answer to part d (above), determine the expected difference in steady state temperature of the Earth during the Cretaceous compared to the present (+15°C). Assume all other constants are unchanged from problem set 1, and that f=61%. 4e. How does your value from 4e compare with that from question 3b? Identify potential causes of any discrepancies. 5. During the Cretaceous, much of the global temperature increase occurred at high latitudes (Arctic and Antarctic) compared to recent times. What impact would these high latitude high temperatures have had on ocean circulation?