机经真题 1 Passage 2

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Cryovolcanism on Titan

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Which of the following can be inferred from paragraph 4 about potassium on Titan?

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  • A
    Potassium is one of the most common elements on Titan's surface.
  • B
    Cryovolcanism causes potassium to combine with other material in Titan's rocks.
  • C
    Potassium was one of the first elements directly detected by the Huygens spacecraft.
  • D
    Rocks containing potassium are denser than most other materials on Titan.
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正确答案: D

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  • Titan, the largest moon orbiting the planet Saturn, has long been thought to be a likely place for volcanic activity. Volcanic activity requires internal heat. Titan's large size and substantial density suggest that plenty of gravitational and radioactively generated energy is available for melting its interior. Titan has a substantial layer of water-ammonia liquid lying beneath its surface. Therefore, unlike volcanism on Earth, which is the eruption of molten (melted) rock, volcanism on Titan would be cryovolcanism, which is essentially the eruption of icy water, sometimes mixed with other materials-likely ammonia and methane in Titan's case



    Titan's thick atmosphere is about ninety-five percent nitrogen, with a few percent of methane. The methane in Titan's atmosphere is broken down by sunlight so that it recombines with other constituents of the atmosphere, forming organic compounds such as ethane.For this process to continue, the methane must somehow be replenished. One thought is that large liquid bodies on the surface (perhaps liquid methane or ethane) could re-supply the atmospheric methane; at Titan's temperatures (-176°C at the surface), methane behaves much like water on Earth. The Cassini spacecraft, which orbited Saturn and studied the planet and its moons, revealed large bodies of liquid on Titan's surface, perhaps enough to replenish the atmospheric methane, but another possibility is that cryovolcanism supplies methane and other gases to the atmosphere.



    Cassini results suggest that cryovolcanism has indeed been a significant geological process on Titan. The craft carries a radar instrument that can peer through the clouds and haze to the never-before seen surface. It showed that several large liquid flows were spread across Titan's frigid landscape. Some, particularly those that appear to come out of craters (surface depressions), are likely to be cryovolcanic, though some researchers argue that some of these flows could possibly be rivers. Titan's surface has fluvial (river) activity, as shown by plenty of branched channels, indicating that rivers of liquid methane run there. Cryovolcanism can also cause flows, so the challenge is to identify which process caused a particular flow deposit. Some of the flows seen in the radar images are more likely to be cryovolcanic than fluvial, particularly those that appear to come out of craters. The craters are elongated rather than circular, indicating origin by volcanic eruptions rather than by impact (collision with objects from space). The association of flows with non-impact craters is hard to explain by any process other than volcanism. Titan may still be actively cryovolcanic: Cassini observed period brightening of infrared light at two locations that could not be explained by changes in cloud cover. It is possible that active cryovolcanism, perhaps in the form of the release of gas, causes the brightness changes. When the radar instrument observed these locations, they showed flow features that could be due to cryovolcanism.



    Whether or not Titan is currently actively volcanic, it is likely that it was in the past. The Huygens spacecraft, which landed on Titan on January 14, 2005, obtained other evidence that cryovolcanism may have occurred on Titan. Although the amazing surface images did not show any features that could be unambiguously interpreted as cryovolcanic, Huygens did make a surprising finding. It detected a variant of the element argon in Titan's atmosphere. This variant is formed from the element potassium, and its presence in the quantities measured means that the atmosphere must be in communication with a reservoir of potassium. Titan is large enough to have differentiated, that is, it evolved into compositionally distinct layers, with the denser materials sinking to the center. Therefore, it is likely that most of the potassium-bearing material is in the rocks that form Titan's core (center). Cryovolcanism would be one means by which this material might be brought to the surface.


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    解析

    A.  这个选项不正确。文中并没有提到钾是 Titan 表面最常见的元素。相反,文中提到钾主要存在于 Titan 核心的岩石中,而不是表面(“Therefore, it is likely that most of the potassium-bearing material is in the rocks that form Titan's core”)。

    B. 这个选项不正确。文中提到钾的变种存在于大气中,表明有一部分物质可能通过冰火山活动从核心被带到表面,但并没有说明冰火山导致钾与其他物质结合。

    C. 这个选项不正确。文中提到 Huygens 探测器探测到氩元素的变种,该变种是从钾元素形成的,但没有具体说明钾是最早被探测到的元素之一。

    D.  这是正确答案。文中提到,“Titan is large enough to have differentiated, that is, it evolved into compositionally distinct layers, with the denser materials sinking to the center”,并进一步解释说钾的物质可能存在于形成 Titan 核心的岩石中。这表明含钾的岩石比大多数其他物质密度更高,因此沉入中心。

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