Global River Topology (GRIT): A Bifurcating River Hydrography

Wortmann, M.; Slater, L.; Hawker, L.; Liu, Y.; Neal, J.; Zhang, B.; Schwenk, J.; Allen, G.; Ashworth, P.; Boothroyd, R.; Cloke, H.; Delorme, P.; Gebrechorkos, S. H.; Griffith, H.; Leyland, J.; McLelland, S.; Nicholas, A. P.; Sambrook-Smith, G.; Vahidi, E.; Parsons, D.; Darby, S. E.

doi:10.1029/2024WR038308

Global River Topology (GRIT): A Bifurcating River Hydrography

Wortmann, M.; Slater, L.; Hawker, L.; Liu, Y.; Neal, J.; Zhang, B.; Schwenk, J.; Allen, G.; Ashworth, P.; Boothroyd, R.; Cloke, H.; Delorme, P.; Gebrechorkos, S. H.; Griffith, H.; Leyland, J.; McLelland, S.; Nicholas, A. P.; Sambrook-Smith, G.; Vahidi, E.; Parsons, D.; Darby, S. E.

Authors

M. Wortmann

L. Slater

L. Hawker

Y. Liu

J. Neal

B. Zhang

J. Schwenk

G. Allen

P. Ashworth

R. Boothroyd

H. Cloke

P. Delorme

S. H. Gebrechorkos

H. Griffith

J. Leyland

Professor Stuart McLelland S.J.McLelland@hull.ac.uk
Deputy Director of the Energy and Environment Institute

A. P. Nicholas

G. Sambrook-Smith

E. Vahidi

D. Parsons

S. E. Darby

Abstract

Existing global river networks underpin a wide range of hydrological applications but do not represent channels with divergent river flows (bifurcations, multi-threaded channels, canals), as these features defy the convergent flow assumption that elevation-derived networks (e.g., HydroSHEDS, MERIT Hydro) are based on. Yet, bifurcations are important features of the global river drainage system, especially on large floodplains and river deltas, and are also often found in densely populated regions. Here we developed the first raster and vector-based Global RIver Topology that not only represents the tributaries of the global drainage network but also the distributaries, including multi-threaded rivers, canals and deltas. We achieve this by merging a 30 m Landsat-based river mask with elevation-generated streams to ensure a homogeneous drainage density outside of the river mask for rivers narrower than approximately 30 m. Crucially, we employ the new 30 m digital terrain model, FABDEM, based on TanDEM-X, which shows greater accuracy over the traditionally used SRTM derivatives. After vectorization and pruning, directionality is assigned by a series of elevation, flow angle and continuity approaches. The new global network and its attributes are validated using gauging stations, comparison with existing networks, and randomized manual checks. The new network represents 19.6 million km of streams and rivers with drainage areas greater than 50 km2 and includes 67,495 bifurcations. With the advent of hyper-resolution modeling and artificial intelligence, GRIT is expected to greatly improve the accuracy of many river-based applications such as flood forecasting, water availability and quality simulations, or riverine habitat mapping.

Citation

Wortmann, M., Slater, L., Hawker, L., Liu, Y., Neal, J., Zhang, B., Schwenk, J., Allen, G., Ashworth, P., Boothroyd, R., Cloke, H., Delorme, P., Gebrechorkos, S. H., Griffith, H., Leyland, J., McLelland, S., Nicholas, A. P., Sambrook-Smith, G., Vahidi, E., Parsons, D., & Darby, S. E. (2025). Global River Topology (GRIT): A Bifurcating River Hydrography. Water Resources Research, 61(5), Article e2024WR038308. https://doi.org/10.1029/2024WR038308

Journal Article Type	Article
Acceptance Date	Mar 7, 2025
Online Publication Date	May 15, 2025
Publication Date	2025-05
Deposit Date	May 30, 2025
Publicly Available Date	May 30, 2025
Print ISSN	0043-1397
Publisher	American Geophysical Union
Peer Reviewed	Peer Reviewed
Volume	61
Issue	5
Article Number	e2024WR038308
DOI	https://doi.org/10.1029/2024WR038308
Public URL	https://hull-repository.worktribe.com/output/5184728