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Volume 8, Issue 9 (Suppl)

J Earth Sci Clim Change

ISSN: 2157-7617 JESCC, an open access journal

Climate Congress 2017

October 16-17, 2017

October 16-17, 2017 Dubai, UAE

3

rd

World Congress on

Climate Change and Global Warming

On the correlation structure between surface soil moisture and vegetation water content with global

carbon fluxes

Khaled Ghannam

1, 2

1

Duke University, USA

2

Princeton University, USA

Statement of the Problem:

The anticipated increase in the frequency and severity of droughts across the globe will intensify

water stress on terrestrial ecosystems and hence on food security. Regional land surface and global climate models largely rely

on satellite remotely sensed surface soil moisture (typically the top 5 cm of the soil) to predict vegetation response (carbon

uptake) to water stress or otherwise to characterize land surface fluxes. Ideally, however, the deeper soil layer root-zone

moisture reflected by nighttime vegetation water content is the correct measure of such feedbacks. Differences in rooting depth

and vegetation plant functional types (crops, forests, grasslands, etc.) also play an important role in dictating where and when

the fluctuations in vegetation water content can be more predictive of carbon fluxes than the surface soil moisture.

Methodology &Theoretical Orientation:

In this study, we compile global data sets of surface soil moisture, vegetation water

content and global carbon fluxes from satellite remote sensing (NOAA’s AVHRR) spanning the years 2002 to 2010. The data

is at high temporal (daily) and spatial (0.25

o

×0.25

o

) resolution allowing the analysis to extend to multiple time scales. The

correlation structure between surface soil moisture and/or vegetation water content with global carbon uptake is analyzed

across all climatic regimes and plant functional types across the globe. The statistics of mutual information content across

several plant physiologic response mechanisms, commonly referred to as isohydric vs. anisohydric response is also examined.

Findings:

The preliminary results indicate that the tropics (e.g., Amazonia), dominated by isohydric shallow root plants, tend

to exhibit weaker dependence on water content than higher latitudes with generally vegetation water content having stronger

correlation with carbon fluxes. Isohydric plant species show less dependence on shallow soil moisture, while fluctuations in

daytime vs. nighttime vegetation water content have strong correlation with anisohydric species’ response.

Conclusion:

This study improves the predictability of global carbon fluxes and proposes the incorporation of vegetation water

content as a reliable surrogate of shallow soil moisture in global models.

khaled.mghannam@gmail.com

J Earth Sci Clim Change 2017, 8:9 (Suppl)

DOI: 10.4172/2157-7617-C1-034