Assume, the average radiation intake of the planet earth increases by 120 W/m² momentarily. The planet therefore leaves its thermal equilibrium and starts heating up (neglect additional thermal losses). The total weight of the planet is 6 x 1024 kg. Assume, that we have 1.1 x 10⁹ km³ of sea water and the rest of the planet is rock. The heat capacity of sea water is 3.6 kJ / kg K, the density is 1 t/m². The heat capacity of rock is 1.1 kJ/kg K, the density is 2.9 t/m². Take the cross section area of the planet as A = r² with r being 6500 km. How long does it take, until the temperature of the earth has risen by 3°C? Assume, the full mass of the planet is always on the same temperature. Why is the result much lower than you'd expect? Which of the assumptions is not realistic?

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Assume, the average radiation intake of the planet earth increases by 120 W/m² momentarily. The planet therefore leaves its thermal equilibrium and starts heating up (neglect additional thermal losses). The total weight of the planet is 6 x 1024 kg. Assume, that we have 1.1 x 109 km³ of sea water and the rest of the planet is rock. The heat capacity of sea water is 3.6 kJ/ kg K, the density is 1 t/m³. The heat capacity of rock is 1.1 kJ/ kg K, the density is 2.9 t/m². Take the cross section area of the planet as A = r² with r being 6500 km. How long does it take, until the temperature of the earth has risen by 3°C? Assume, the full mass of the planet is always on the same temperature. Why is the result much lower than you'd expect? Which of the assumptions is not realistic?