Maps of surface chlorophyllous pigment (Chl a + Pheo a) are currently produced from ocean color sensors. Transforming such maps into maps of primary production can be reliably done only by using light-production models in conjunction with additional information about the columnintegrated pigment content and its vertical distribution.As a preliminary effort in this direction, -4,000 vertical profiles of pigment (Chl a + Pheo a) determined only in oceanic Case 1 waters have been statistically analyzed. They were scaled according to dimensionless depths (actual depth divided by the depth of the euphotic layer, Z,) and expressed as dimensionless concentrations (actual concentration divided by the mean concentration within the euphotic layer). The depth Z,, generally unknown, was computed with a previously developed bio-optical model. Highly significant relationships were found allowing (C>,,,, the pigment content of the euphotic layer, to be inferred from the sur!ace concentration, C,, observed within the layer of one penetration depth. According to their C,, values (ranging from 0.01 to > 10 mg m-3), we categorized the profiles into seven trophic situations and computed a mean vertical profile for each. Between a quasi-uniform profile in eutrophic waters and a profile with a strong deep maximum in oligotrophic waters, the shape evolves rather regularly. The wellmixed cold waters, essentially in the Antarctic zone, have been separately examined. On average, their profiles are featureless, without deep maxima, whatever their trophic state. Averaged values of p, the ratio of Chl a to (Chl a + Pheo a), have also been obtained for each trophic category.The energy stored by photosynthesizing algae, once normalized with respect to the integrated chlorophyll biomass (C),,, is proportional to the available photosynthetic energy at the surface via a parameter #*, which is the cross-section for photosynthesis per unit of areal chlorophyll. By taking advantage of the relative stability of #*, we can compute primary production from ocean