• Aucun résultat trouvé

MUREX: a land-surface field experiment to study the annual cycle of the energy and water budgets

N/A
N/A
Protected

Academic year: 2021

Partager "MUREX: a land-surface field experiment to study the annual cycle of the energy and water budgets"

Copied!
18
0
0

Texte intégral

Loading

Figure

Fig. 1. Photograph of the central part of the MUREX fallow site (at the end of 1996) with some of the instrumentation
Fig. 3. As in Fig. 2, except for air temperature and humidity, T a and q a and wind speed
Fig. 4. Monthly sums of the measured ¯uxes (net radiation, Rn; sensible heat ¯ux; H; latent heat ¯ux LE; and ground heat ¯ux, G over the MUREX  fal-low in 1995, 1996, and 1997 (note that LE is estimated by di€erence), and a temporal  dia-gram of the soil volumetric moisture within the 1.35 m soil layer as measured with a  neu-tron probe over the MUREX fallow
Fig. 5. Cumulative precipita- precipita-tion and positive values of the water excess derived from the total soil moisture content, precipitation and  evapotran-spiration measurements over the MUREX fallow in 1995, 1996, and 1997
+7

Références

Documents relatifs

is favoured by an applied magnetic field Actually both the transition temperature and the associated specific heat anomaly are strongly increased by a magnetic

Hence if director fluctuations are unimportant within the mean field, we can say immediately that the transition to the smectic state will occur at a temperature AT,

This paper describes a methodology to estimate sensible and latent heat fluxes on the basis of net radiation, surface radiometric temperature measurements and informa- tion

[r]

Modeling of Local Blue Ice Mass Balance [ 38 ] Model results were compared with observations of surface elevation (Figure 4a), surface temperature (Figure 4b) and with measurements

There are a few issues that arise from the inherent characteristics of PCM. The low heat transfer rate between the heat transfer fluid and PCM leads to less efficient thermal

The slow changes in sensible heat and atmospheric radiative cooling are derived from the PDRMIP mean results of slow changes per global-mean surface temperature changes multiplied

Given this, we advance an iterative user- centered design approach to ensure that empiric users grasps (sense-making) of the intentionality of authors is both