Nepal Drought Monitor

Motivation

Nepal is acutely vulnerable to drought. Around 60 percent of the Nepalese households are engaged in agriculture (National Statistics Office, 2022), and the agricultural sector supports the livelihoods of roughly two-thirds of the total population (FAO, 2023). Economic losses in farm and off-farm sectors over the last five years alone have amounted to NRs. 415 billions, excluding infrastructure damage due to climate change (National Statistics Office, 2022). Drought risk is growing, particularly during the pre-monsoon and winter seasons, when declining rainfall combines with rising temperatures and increased agricultural water demand. Winter droughts are becoming more frequent, especially in the western Terai, where a persistent downward trend in precipitation has been documented since mid-1990s (IFRC, 2025), threatening food security and livelihoods for rain-fed farming communities. Trend analyses across multiple stations and time scales indicate that both the severity and frequency of drought events are increasing across Nepal (Dhital et al., 2015, Sharma et al., 2021, Bhandari et al., 2021, Dahal et al., 2015).

Despite this vulnerability, Nepal currently lacks a high-resolution, continuously gridded drought monitoring system grounded in physically based model. Earth observation based tools do exist for Nepal, most notably the ICIMOD National Agricultural Drought Watch developed under the SERVIR-HKH Initiative and the broader Regional Drought Monitoring and Outlook System for the Hindu Kush Himalaya (ICIMOD, 2024b). These systems provide valuable district-level aggregated drought indicators based on remote sensing indices. However, they do not provide the spatially continuous, process-based soil moisture characterization at high resolution that is possible with a fully distributed hydrological model. The Nepal Drought Monitor (NDM) addresses this specific gap by applying hydrological modelling approach from proven operational systems such as the German Drought Monitor and the emerging European Drought Monitor directly to Nepal's terrain and hydro-climatic conditions.

Foundation

Nepal Drought Monitor (NDM) takes inspiration from the scientific foundation of the German Drought Monitor (GDM), which is also the precursor of the European Drought Monitor (EDM). Like EDM, NDM's workflow closely follows that of the GDM, while the operational control for EDM and NDM are based on the ecFlow - the workflow manager from ECMWF. In fact, the NDM is based on the git fork of EDM's ecFlow suite and the updates between the two are synced continuously. Like GDM, the NDM aims to demonstrate the value of hydrological-model-based drought indicators and position itself as a useful tool for near-real-time drought characterization and communication to the public and policymakers in Nepal.

What is the Soil Moisture Index (SMI)?

The Soil Moisture Index (SMI) quantifies the current soil moisture state relative to the long-term soil moisture history at each grid cell at given day of the year. The soil moisture in a grid cell that is mostly wet can have different SMI class compared to a grid cell that is mostly dry with the same soil moisture. Therefore, the soil moisture interpretation of SMI should be made for the given location than comparison across locations. The SMI ranges from 0, the driest condition on record, to 1, the wettest condition on record, and is classified into drought categories analogous to those used in the US Drought Monitor, the GDM, and the EDM.

¹Svoboda et al. (2002) BAMS ²Zink et al. (2016) ERL ³Boeing et al. (2022) HESS

Collaboration

The NDM is a joint research initiative between the Institute of Engineering (IOE), Tribhuvan University, Kathmandu, Nepal, and the Helmholtz Centre for Environmental Research (UFZ), Leipzig, Germany. This partnership combines UFZ's expertise in large-scale distributed hydrological modelling and operational drought monitoring with IOE's deep knowledge of Nepal's hydro-climatic system, local data networks, and regional context.

The NDM team welcomes collaboration from interested institutions, government agencies, and research groups working on drought, water resources, and climate adaptation in Nepal and the broader Hindu Kush Himalaya region, to further enhance the system, expand its reach, and support its eventual operationalisation.

Disclaimer

The NDM is currently under active research and remains in a prototype phase. The present version of the system is intended for scientific evaluation, stakeholder engagement, and collaborative development, and is undergoing continuous testing. The results should therefore be interpreted with appropriate caution.

Call for collaborations

Through this publicly accessible platform, we are committed to transparently sharing drought information generated by the NDM, including current testing phase, with the broader community. We actively welcome collaboration with national and international institutions to further enhance the system, expand its reach, and support its eventual operationalisation.

NDM
Operationalisation Status

Nepal Drought Monitor (NDM)

Total2m

Drought conditions for Nepal in the past 14 days in terms of soil moisture index (SMI). Generated by the Nepal Drought Monitor (v0.0.1) operational system at UFZ, in collaboration with IOE, Nepal — Drought conditions for Nepal in the past 14 days in terms of soil moisture index (SMI) in the total soil column (2m). Generated by the Nepal Drought Monitor (v0.0.1) operational system at UFZ, in collaboration with IOE, Nepal.

Operationalization Status of NDM

The NDM is currently in testing phase. The pilot model chain is implemented with on going addition of subsequent complexities. Please find the updated status below:

Incorporated tasks

version 0.0.1

01.05.2026

The first operational version with 8 hours latency.
Model chain operationalized in ecFlow workflow manager
Runtime: ~ 10 minutes
ERA5 land (10 km) pre and txxx download from the CDS with 7 days latency
ERA5 land regridded to 12 km using conservative remapping
IMERG Early (10 km) precipitation retrieved, extending pre to NRT
IMERG Early regridded to 12 km using conservative remapping
Daily temperature climatology used for extending txxx to NRT.
mHM run at 1 km using the 1km ERA5 land (-6 day) + IMERG Early & Txxx climatology (-5 day to -1 day)
SMI for total soil column
SMI reference period: 1960-1999
SMI graphics upload to UFZ files server
Live link between this webpage and the UFZ files server
Notification email (daily) on the success/failure of the suite

Pending tasks:

Multiple soil layer based SMI
Implementation of EDK in the suite
Implementation of Bias correction of both ERA5 land and EO-based forcings using Gridded Observation Station Data (N-obs), at 1 km

Collaborating Institutions:

Contact Persons:

Pallav Kumar Shrestha

pallav-kumar.shrestha@ufz.de

Bibek Pathak

077bce033.bibek@pcampus.edu.np

Group leaders:

Luis Samaniego

luis.samaniego@ufz.de

Vishnu Prasad Pandey

vishnu.pandey@pcampus.edu.np

Contact

Head
Prof. Dr. Sabine Attinger
Department of Computational Hydrosystems
tbl-modmon@ufz.de

Deputy Head
Prof. Dr. Luis Samaniego
Department of Computational Hydrosystems
luis.samaniego@ufz.de

Assistance
Nora Pabst
Phone +49 341 6025-2367

Sindy Bleiholder
Phone +49 341 6025-1250

Susanne Gangloff
Phone +49 341 6025-2533

sekces@ufz.de

Permoserstraße 15 | 04318 Leipzig

News / Press

Aug 2025

New research published in Nature Food by Batool et al. (2025) analyses the effectiveness of EU nitrogen reduction targets. Under the “Farm to Fork” (F2F) strategy of the “Green Deal”, the EU Commission aims to reduce nutrient losses by 50% by 2030 by requiring EU countries to cut chemical fertiliser use by 20%. As shown in our work such a uniform reduction in fertilizer use would not be sufficient.

May 2024

New research published in Nature Communications by Hussian et al., (2024) emphasizes the game-changing potential of near-real-time and impact-based flood prediction. Their study demonstrates a 10-meter floodplain inundation hindcast of the 2021 European Summer Flood, showcasing a 17-hour lead time for better disaster preparedness. Impact-based early warnings can empower local authorities with crucial data on citizens at-risk for targeted emergency responses.

July 30, 2023

Hitze und Dürre - Interview with climate researcher Jakob Zscheischler
in Deutschlandfunk (only in German, 10:50 min) Link to interview

May 16, 2023

Start of ESA funded project 4DHydro

The overarching objective of 4DHydro is to foster collaborations between the Earth Observation (EO) water cycle community developing novel high-resolution EO data products, and the land surface and hydrological modelling community (LSM/HM) engaged in advancing hyperresolution modelling of the hydrological cycle at regional and continental scales. By involving several European institutions 4DHydro will assess and improve data sets of EO as well as synchronize EO products and LSM/HM models in order to improve predictions of the hydrological system. Overall, it will assist end-users and decisions-makers as well as the EU Destination Earth initiative. The project’s kick-off meeting will take place in Leipzig on 21st of June 2023.

Jan 30, 2023

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The following paper received the ASCE-EWRI 2023 Award for Best Case Study in the Journal of Hydrologic Engineering.

Mai, J. , B. A. Tolson, H. Shen, É. Gaborit, V. Fortin, N. Gasset, H. Awoye, T. A. Stadnyk, L. M. Fry, E. A. Bradley, F. Seglenieks, A. G. Temgoua, D. G. Princz, S. Gharari, A. Haghnegahdar, M. E. Elshamy, S. Razavi, M. Gauch, J. Lin, X. Ni, Y. Yuan, M. McLeod, N. B. Basu, R. Kumar, O. Rakovec, L. Samaniego, S. Attinger, N. K. Shrestha, P. Daggupati, T. Roy, S. Wi, T. Hunter, J. R. Craig, and A. Pietroniro (2021):
The Great Lakes Runoff Intercomparison Project Phase 3: Lake Erie (GRIP-E)
Journal of Hydrologic Engineering, 26(9), 05021020. Accepted Feb 16, 2021.

https://ascelibrary.org/doi/10.1061/%28ASCE%29HE.1943-5584.0002097

Dec 1, 2022

Award Poster Masooma Batool

Masooma Batool won the "Best student poster award" at the XXI International Nitrogen Workshop.
This conference, hosted by ETSIAAB, Universidad Politécnica de Madrid, brought together nearly 300 papers from authors from 40 countries in Madrid, Spain, October 24-28, 2022.
At the conference, Masooma and her colleagues presented long-term trends in soil nitrogen (N) surplus across Europe (1850-2019). Excess N provides information on the trends and spatial distribution of N surplus in soil systems across Europe, highlighting agricultural areas in Central Europe as nitrogen hotspots. These areas have undergone dramatic changes over the past 150 years. Importantly, we show that estimates of N surplus are subject to large uncertainties, requiring explicit consideration of these uncertainties when analyzing past trends in N surplus.

Nov 15, 2022

Earthrise - Mission Klima
How our research contributes to climate mitigation and adaptation is demonstrated in this WELT report.

Video at www.welt.de (only in German)

05:50': Hohes Holz research station
10:40': FORMIND in the Vislab
15:45': Fragmentation of forests
43:00': FORMIND and climate scenarios

Oct 12, 2022

Dr. Husain Najafi won the UFZ Young Scientist Award for Applied Research 2022. The award goes to him for his excellence and dedication in development of the operational drought forecasting system in Germany and investigation of 2021 summer flood predictability. Hydrological forecasting systems are the fundamental component of early warning systems - disaster risk reduction.

Older news are stored in the news archive.

New publications

Najafi, H., Shrestha, P.K., Rakovec, O. et al. High-resolution impact-based early warning system for riverine flooding. Nat Commun 15, 3726 (2024). https://doi.org/10.1038/s41467-024-48065-y
Henniger, H., Huth, A., Frank, K., & Bohn, F. J. (2023). Creating virtual forests around the globe and analysing their state space. Ecological Modelling, 483, 110404. https://doi.org/10.1016/j.ecolmodel.2023.110404

In this paper we present the "Forest Factory 2.0″ algorithm, which generates various virtual forest stands for different biomes on Earth. To demonstrate the potential of this approach, we analyse different forest-structure->ecosystem-function relationships across biomes.
Friedrich Boeing, Oldrich Rakovec, Rohini Kumar, Luis Samaniego, Martin Schrön, Anke Hildebrandt, Corinna Rebmann, Stephan Thober, Sebastian Müller, Steffen Zacharias, Heye Bogena, Katrin Schneider, Ralf Kiese, Sabine Attinger, and Andreas Marx. High-resolution drought simulations and comparison to soil moisture observations in Germany. Hydrol. Earth Syst. Sci., 26, 5137–5161, 2022. https://doi.org/10.5194/hess-26-5137-2022

In this paper, we deliver an evaluation of the second generation operational German drought monitor ( https://www.ufz.de/duerremonitor ) with a state-of-the-art compilation of observed soil moisture data from 40 locations and four different measurement methods in Germany. We show that the expressed stakeholder needs for higher resolution drought information at the one-kilometer scale can be met and that the agreement of simulated and observed soil moisture dynamics can be moderately improved.
Mahnken, M., Cailleret, M., Collalti, A., Trotta, C., Biondo, C., D’Andrea, E., ... & Reyer, C. P. O. (2022). Accuracy, realism and general applicability of European forest models. Global Change Biology. DOI: 10.1111/gcb.16384
Pacheco-Labrador, J., Weber, U., Ma, X., Mahecha, M. D., Carvalhais, N., Wirth, C., Huth, A., Bohn, F. J., Kraemer, G., Heiden, U., FunDivEUROPE members, and Migliavacca, M.: EVALUATING THE POTENTIAL OF DESIS TO INFER PLANT TAXONOMICAL AND FUNCTIONAL DIVERSITIES IN EUROPEAN FORESTS, Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci., XLVI-1/W1-2021, 49–55, 2022. DOI: 10.5194/isprs-archives-XLVI-1-W1-2021-49-2022
Bevacqua, E., De Michele, C., Manning, C., Couasnon, A., Ribeiro, A.F.S., Ramos, A.M., Vignotto, E., Bastos, A., Blesić, S., Durante, F., Hillier, J., Oliveira, S.C., Pinto, J.G., Ragno, E., Rivoire, P., Saunders, K., van der Wiel, K., Wu, W., Zhang, T., Zscheischler, J. (2021): Guidelines for Studying Diverse Types of Compound Weather and Climate Events. Earth Future. 10.1029/2021EF002340
Najafi H, Robertson AW, Massah Bavani AR, Irannejad P, Wanders N, Wood EF. Improved multi-model ensemble forecasts of Iran's precipitation and temperature using a hybrid dynamical-statistical approach during fall and winter seasons. Int
J Climatol. 2021;1–28. DOI: 10.1002/joc.7148

Hari, V., Rakovec, O., Markonis, Y. et al. Increased future occurrences of the exceptional 2018–2019 Central European drought under global warming. Sci Rep 10, 12207 (2020). DOI: 10.1038/s41598-020-68872-9

Schmidt, L., Heße, F., Attinger, S., Kumar, R., (2020): "Challenges in applying machine learning models for hydrological inference: A case study for flooding events across Germany", Water Resources Research DOI: 10.1029/2019WR025924

Jing, M., Kumar, R., Heße, F., Thober, S., Rakovec, O., Samaniego, L., Attinger, S., (2020): "Assessing the response of groundwater quantity and travel time distribution to 1.5, 2, and 3 °C global warming in a mesoscale central German basin", Hydrology and Earth System Sciences DOI: 10.5194/hess-24-1511-2020

Sep 2, 2022

The collaborative project "Standardisiertes Monitoring von Wachstumsreaktionen wichtiger Waldbaumarten auf klimatische Extremereignisse" (MW³) with participation of the UFZ will develop a standardized monitoring system and protocol to record growth responses of important Central European forest tree species with a focus on climatic extremes. Future extreme events and their impact on forest carbon fluxes in Germany will be analyzed using smart models.