Coupling the Soil-Vegetation-Atmosphere-Transfer Scheme ORCHIDEE to the agronomy model STICS to study the influence of croplands on the European carbon and water budgets

Agronomie Pub Date : 2004-09-01 DOI:10.1051/AGRO:2004038

N. Noblet-Ducoudré, S. Gervois, P. Ciais, N. Viovy, N. Brisson, B. Séguin, A. Perrier

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引用次数: 88

Abstract

Agriculture is still accounted for in a very simplistic way in the land-surface models which are coupled to climate models, while the area it occupies will significantly increase in the next century according to future scenarios. In order to improve the representation of croplands in a Dynamic Global Vegetation Model named ORCHIDEE (which can be coupled to the IPSL 1 climate model), we have (1) developed a procedure which assimilates some of the variables simulated by a detailed crop model, STICS, and (2) modified some parameterisations to avoid inconsistencies between assimilated and computed variables in ORCHIDEE. Site simulations show that the seasonality of the cropland-atmosphere fluxes of water, energy and CO 2 is strongly modified when more realistic crop parameterisations are introduced in ORCHIDEE. A more realistic representation of wheat and corn croplands over Western Europe leads to a drying out of the atmosphere at the end of summer and during autumn, while the soils remain wetter, specially at the time when winter crops are sowed. The seasonality of net CO 2 uptake fluxes is also enhanced and shortened.

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将土壤-植被-大气-转移方案ORCHIDEE与农学模型STICS耦合，研究农田对欧洲碳和水收支的影响

在与气候模式相结合的陆地表面模式中，农业仍然以非常简单的方式被考虑在内，而根据未来的情景，农业所占的面积将在下个世纪显著增加。为了改善ORCHIDEE动态全球植被模型(可与IPSL 1气候模型耦合)中农田的表示，我们(1)开发了一种程序，可以同化由详细作物模型(STICS)模拟的一些变量;(2)修改了一些参数化，以避免同化变量与ORCHIDEE中计算变量之间的不一致。现场模拟表明，当在ORCHIDEE中引入更真实的作物参数时，农田-大气水、能量和CO 2通量的季节性被强烈改变。西欧的小麦和玉米农田在夏末和秋季会导致大气干燥，而土壤保持湿润，特别是在播种冬季作物的时候。净co2吸收通量的季节性也增强和缩短。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Agronomie

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