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Chou C.,Academia Sinica, Taiwan | Chou C.,National Taiwan University | Chiang J.C.H.,University of California at Berkeley | Lan C.-W.,Civil Aeronautics Administration | And 3 more authors.
Nature Geoscience | Year: 2013

Global temperatures have risen over the past few decades. The water vapour content of the atmosphere has increased as a result, strengthening the global hydrological cycle. This, in turn, has led to wet regions getting wetter, and dry regions drier. Climate model simulations suggest that a similar intensification of existing patterns may also apply to the seasonal cycle of rainfall. Here, we analyse regional and global trends in seasonal precipitation extremes over the past three decades, using a number of global and land-alone observational data sets. We show that globally the annual range of precipitation has increased, largely because wet seasons have become wetter. Although the magnitude of the shift is uncertain, largely owing to limitations inherent in the data sets used, the sign of the tendency is robust. On a regional scale, the tendency for wet seasons to get wetter occurs over climatologically rainier regions. Similarly, the tendency for dry season to get drier is seen in drier regions. Even if the total amount of annual rainfall does not change significantly, the enhancement in the seasonal precipitation cycle could have marked consequences for the frequency of droughts and floods. © 2013 Macmillan Publishers Limited. All rights reserved.

Yu M.-M.,National Taiwan Ocean University | Hsu C.-C.,Civil Aeronautics Administration
International Journal of Sustainable Transportation | Year: 2012

The aim of this article is to investigate service productivity change and its components at selected domestic airports in Taiwan. Based on the decomposition, we isolate the contributions of magnitude change and biased changes to the physical technology change. The results reveal that service productivity growth is at the rate of about 1.3% per year on average, and is accompanied by quality productivity growth of 19.5%, while physical productivity declined -14.4%. The decomposition of physical technology change shows that declining growth results from the pure magnitude regress (-8.4%) with slight output biased technological progress (2.2%). © Taylor & Francis Group, LLC.

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