<jats:title>ABSTRACT</jats:title><jats:p>Recently released spores of the kelps <jats:italic>Macrocystis pyrifera</jats:italic> (L.) C. Ag., <jats:italic>Nereocystis luetkeana</jats:italic> (Mert.) Post. and Rupr., <jats:italic>Laminaria farlowii</jats:italic> Setch., and <jats:italic>Pterygophora californica</jats:italic> Rupr. had different levels of net photosynthesis. Spore‐specific photosynthesis–irradiance relationships were similar in many respects for <jats:italic>M. pyrifera, N. luetkeana</jats:italic>, and <jats:italic>L. farlowii</jats:italic> spores. All three species had low rates of net light‐saturated photosynthesis. In contrast, spores of <jats:italic>P. californica</jats:italic> had higher photosynthetic potential and overall net photosynthesis than the other three species. On a cell carbon basis, however, photosynthetic rates in <jats:italic>N. luetkeana</jats:italic> spores were similar to those of <jats:italic>P. californica</jats:italic> spores and higher than those of <jats:italic>M. pyrifera</jats:italic> spores. Chlorophyll <jats:italic>a</jats:italic> content of spores varied 10‐fold among species. The rank order of significant differences in chlorophyll <jats:italic>a</jats:italic> content was <jats:italic>P. californica > L. farlowii > N. luetkeana > M. pyrifera.</jats:italic> As a result, chlorophyll‐specific measurements suggest <jats:italic>M. pyrifera</jats:italic> and <jats:italic>N. luetkeana</jats:italic> spores had much higher quantum efficiency and photosynthetic potential than either <jats:italic>P. californica</jats:italic> or <jats:italic>L. farlowii</jats:italic> spores. Maternal carbon and nitrogen investment significantly differed in spores of <jats:italic>M. pyrifera, N. luetkeana</jats:italic>, and <jats:italic>P. californica</jats:italic> with <jats:italic>P. californica > M. pyrifera > N. luetkeana.</jats:italic> Carbon content in spores of each of these three species increased by about 30% during 12 h of saturating irradiance. We suggest that the photosynthetic capabilities of and maternal investment in spores may be related to the spore as a unit of dispersal, to the reproductive ecology of the parental sporophytic stages, and to the growth and physiology of the germling gametophyte stages.</jats:p>