Presentations, publications and CV

Publication record

1. Cheng, H., W. Wang, I. de Graaf, J. Lu, S. van der Kooij, J. Vos, Y. Yao, P. van Oel (2024) Contrasting effects of increasing irrigation efficiency on hydrological drought based on hydrological scenario simulations. Journal of Hydrology, 645. doi: 10.1016/j.jhydrol.2024.132261. 

2. Reinecke, R., S. Gnann, L. Stein, M. Bierkens, I. de Graaf, T. Gleeson, G. Oude Essink, E. H. Sutanudjaja, C. Ruz Vargas (2024) Uncertainty in model estimates of global groundwater depth. Environmental Research Letters, 19, 11. doi:10.1088/1748-9326/ad8587.

3. Van Tiel, M., Aubry-Wake, C., Somers, L., Andermann, C., Avanzi, F., Baraer, M., Chiogna, G., Daigre, C., Das, S., Drenkhan, F., Farinotto, D., Fyffe, C., de Graaf, I., Hanus, S., Immerzeel, W., Koch, F., McKenzie, J., Müller, T., Popp, A., Saidaliyeva, Z., Schaefli, B., Schilling, O., Teagai, K., Thornton, J., Yapiyev, V. (2024) Elucidating cryosphere-groundwater connectivity to unravel the mountain water cycle. Nature Water., 2, 624-637. Doi:10.1038/s44221-024-00277-8.

4. de Graaf, I., B. Marinelli, S. Liu (2024) Global Analysis of Groundwater Pumping from Increased River Capture. Environmental Research Letters, 19,4. Doi:10.1088/1748-9326/ad383d (Invited contribution)

5. Sutanto, S.J., W. A. Syaehuddin, I. de Graaf (2024), Hydrological drought forecast using precipitation data depend on catchment properties and human activities.  Nature Communications Earth&Environment 5, 118. 10.1038/s43247-024-01295-w.

6. Meng, F., R. Reinder, M. Strokal, C. Kroeze, L. Ma, M. Krol, I. de Graaf, Y. Zhao, Y. Wang, X. Du, X. Liu (2024) Setting goals for agricultural nitrogen emission reduction to ensure safe air and groundwater quality: A case study of Quzhou, the North China Plains. Journal of Environmental Management. doi:10.1016/j.jenvman.2023.119737.

7. Mohan, C., T. Gleeson, T. Forstner, J.S. Famiglietti, I. de Graaf (2023) Quantifying groundwater’s contribution to regional environmental flows in diverse hydrological landscapes. Water Resources Research. doi:10.1029/2022WR033153.

8. Pierrat, E., M. Dorber., I. de Graaf, A. Laurent, M. Z. Hauschild, M. Rygaard, V. Barbarossa (2023), Multicompartment Depletion Factors for Water  Consumption on a Global Scale, Environ. Sci. Technol., 57, 10, 4318-4331. doi:10.10321/acs.est.2c04803.

9. Scanlon, B.R., S. Fakhreddine, A. Rateb, I. de Graaf, J. Famiglietti, T. Gleeson, R.Q. Grafton, E. Jobbagy, S. Kebede, S. Rao Kolusu, L. F. Konikow, D. Long, M. Mekonnen, H. Müller Schmied, A. Mukherjee, A. MacDonald, R. C. Reedy, M. Shamsudduha, C. T. Simmons, A. Sun, R. G. Taylor, K. G. Villholth, C. J. Vörösmarty, C. Zeng (2023), Global water resources and the role of groundwater in a resilient water future, Nature Reviews Earth & Environment 4, 87-101. doi:s43017-022-03378-6.

10. de Graaf, I. and K. Stahl (2022), A model comparison assessing the importance of lateral groundwater flows at the global scale, Environ. Res. Letters, 17, 044020. doi: 10.1088/1748-9326/ac50d2.

11. Gleeson, T., Wagener, T., Döll, P., Zipper, S. C., West, C., Wada, Y., Taylor, R., Scanlon, B., Rosolem, R., Rahman, S., Oshinlaja, N., Maxwell, R., Lo, M.-H., Kim, H., Hill, M., Hartmann, A., Fogg, G., Famiglietti, J. S., Ducharne, A., de Graaf, I., Cuthbert, M., Condon, L., Bresciani, E., and Bierkens, M. F. P. (2021), GMD Perspective: The quest to improve the evaluation of groundwater representation in continental to global scale models, Geoscientific Model Development. Doi:10.5194/gmd-14-7545-2021.

12. Herzog, A., B. Hector, J-M. Cohard, J-M. Vouillamoz, F. Lawson, C. Peugeot, I. de Graaf (2021) A parametric sensitivity analysis for prioritizing regolith knowledge needs for modelling water transfers in the West African critical zone, Vadose Zone Journal, 20(6), e20163.

13. Yuanyuan Huang, Phillipe Ciais, Yiqi Luo, Dan Zhu, Yingping Wang, Chunjing Qiu, Daniel S. Goll, Bertrand Guenet, David Makowski, I. de Graaf, Jens Leifeld, Min Jung Kwon, Jing Hu, Laiye Qu (2021) Tradeoff of CO2 and CH4 emissions from peatlands under water-table drawdown, Nature Climate Change, 11(7), 618-622.

14. I. de Graaf, L. Condon, R. Maxwell (2020), Hyper-resolution continental-scale 3D-aquifer parameterization for groundwater modelling, Water Resources Research, 56, 5, doi: 10.1029/2019WR026004.

15. J. Helwig, I. de Graaf, K. Stahl, M. Weiler (2020), Simulation of Groundwater Response to Drought with a High-Resolution Large-Scale Transient Groundwater Model, Water Resources Research, 56, 2, doi:10.1029/2019WRR025441

16. De Graaf, I., T. Gleeson, L.P.H. van Beek, E.H. Sutanudjaja, M.F.P. Bierkens (2019), Limits to global groundwater pumping, Nature, 574, 90-94, doi:10.1038/s41586-019-1594-4. Highly cited (top 1%); editors highlight.

17. Sutanudjaja, E.H., R. van Beek, N. Wanders, Y. Wada, J.H.C. Bosmans, N. Drost, R.J. van der Ent, I. de Graaf, J.M. Hoch, K. de Jong, D. Karssenberg, P. Lopez Lopez, S. Pessenteiner, O. Schmitz, M.W. Straatsma, E. Vannametee, D. Wisser, M.F.P. Bierkens (2018). PCR-GLOBWB 2: a 5 arc-minute global hydrological and water resources model, Geosci. Model Dev. doi.org/10.5194/gmd-20170288. Highly cited (top 1%)

18. De Graaf, I., L.P.H. van Beek, T. Gleeson, N. Moosdorf, O. Schmitz, E.H. Sutanudjaja, M. F. P. Bierkens (2017), A global-scale two-layer transient groundwater model: Development and application to groundwater depletion. Advances in Water Resources, 102, 53-67, doi:10.1016/j.advwateres.2017.01.011.

19. S. Koirala, M. Jung, M. Reichstein, I. de Graaf, G. Camps-valls, K. Ichii, D. Papale, B. Raduly, C. Schwalm, G. Tramontana, and  N. Carvalhais (2017), Determinants of the groundwater-vegetation interaction at the global scale vegetation properties determine groundwater-productivity interactions, Geophysical Research Letters, doi:/10.1002/2017GL072885

20. De Graaf, I. (2016), limits to global groundwater consumption. Effects on groundwater levels and river low flows, published by Faculty of Geosciences, University of Utrecht, The Netherlands, in: Utrecht Studies in Earth Sciences (USES), ISSN 2211-4335.

21. Wada, Y., I. de Graaf. L.P.H. van Beek (2016), High-resolution modelling of human and climate impacts on global water resources, Journal of Advances in Modeling Earth Systems, doi:10.1002/2015MS000618

22. De Graaf, I., E.H. Sutanudjaja, L.P.H. van Beek, and M.F.P. Bierkens (2015), A high resolution global scale groundwater model, Hydrol. Earth Syst. Sci., 19, 823-837,  doi:10.5194/hess-19-823-2015. Editors highlight.

23. De Graaf, I., L.P.H. van Beek, Y. Wada, and M.F.P. Bierkens (2014), Dynamic attribution of global water demand to surface water and groundwater resources: Effects of abstractions and return flows on river discharges, Advances in Water Resources, 64, 21-33, doi:10.1016/j.advwatres.2013.12.002