Against the background of anthropogenic climate change and the need to mitigate CO₂ emissions, the Netherlands is planning for industrial-scale carbon capture and storage in depleted gas fields, where a total practical storage capacity of approximately 1600 Mt is estimated to be available. At present, neither government nor industry have initiated plans for carbon capture and storage in saline formations, and to investigate other storage candidates, we initiated a study of the geological potential for sequestering CO₂ in saline formations in a part of the western Dutch offshore. We identified possible target formations in the Upper Jurassic and Lower Cretaceous fluvial to shoreface sandstones and lower Paleogene shallow-marine sandstones in the West Netherlands Basin and Broad Fourteens Basin, located close to the industrial areas near Amsterdam. Three-dimensional seismic data show that the most promising trapping geometries exist in synclinal structures involving the Lower Cretaceous Vlieland Sandstone Formation, which formed during Late Cretaceous inversion folding. Several scenarios suggest large pore volume space to be available in the subsurface below a depth of 800 m. We envisage that CO₂ would be injected in the deeper parts of the target formation, from which it would migrate under buoyant flow until it reaches the seal and remains stratigraphically trapped. The main risk identified so far relates to the seal integrity of basal Paleogene deposits, against which the storage formation is truncated in places. This academic research project (Deep Offshore Carbon Storage) will continue following the publication of this paper. The next phase will address studies on the seal integrity, reservoir efficiency, and economic feasibility.