​KazNUWMI develops climate-adaptive water infrastructure that integrates engineered and natural systems. Projects explore AI-driven dam operations, sediment control through vegetated buffers and wetlands, and IoT-based diagnostics for aging hydraulic networks.
Nature-based flood management — including retention ponds, riparian forest buffers, and urban green corridors — complements traditional hydraulic structures, enhancing the resilience of cities and agricultural zones to extreme hydrological events. The center also promotes artificial recharge as a strategy for aquifer recovery, seasonal water storage, and ecosystem stabilization under changing climate conditions.

​Combining remote sensing, precision irrigation, and soil-water modeling, this area advances sustainable agricultural production. Research focuses on satellite-guided drip/sprinkler systems that adjust irrigation based on soil moisture and crop needs, supported by solar-powered micro-irrigation for smallholder farms.
Projects incorporate salinity management, nutrient recovery, and reuse of treated wastewater—applying circular economy principles to agricultural water systems. Artificial recharge and subsurface storage of excess irrigation return flows are being tested as part of integrated water–soil–crop management strategies in Kazakhstan’s main irrigation basins.

​​This research area applies machine learning-based watershed modeling, isotope tracing, and eco-hydrological interventions to restore degraded river basins and wetlands. Initiatives address challenges such as Aral Sea rehabilitation, wetland recovery, and industrial pollution control through phytoremediation and biogeochemical buffering systems.
Nature-based approaches—such as floodplain reconnection, reforestation of riparian zones, and constructed recharge wetlands—are used to restore natural hydrological cycles and biodiversity. These systems also contribute to groundwater replenishment and improved ecosystem resilience under climate stress.

​Recognizing the interdependence of water, energy, and agriculture, this area develops integrated governance models for transboundary basins like the Syr Darya and Amu Darya. Research aligns hydropower operations, wastewater reuse, and agricultural productivity with climate adaptation and conflict prevention.
Projects also evaluate policy instruments for artificial recharge, water trading, and nature-based investments, ensuring that Kazakhstan’s water management frameworks promote sustainable growth and regional cooperation.

​​Leveraging multi-sensor satellite data (optical, SAR, LiDAR, hyperspectral) and machine learning, this area develops real-time water monitoring and predictive analytics for surface and groundwater systems. Applications include drought/flood forecasting, snowmelt modeling, and cryosphere dynamics.
AI-driven tools help identify potential recharge zones, assess land-use change impacts on hydrology, and optimize nature-based flood control infrastructure. These insights are embedded into cloud-based decision support platforms for policymakers, utilities, and basin organizations.