Abstract

A range of Carboniferous lycopod megaspore exines have been investigated using 13C magic-angle spinning nuclear magneitc resonance (MAS NMR) spectroscopy. Their composition differs considerably from sporopollenin obtained from an extant lycophyte. The differences observed result in part from varying degrees of diagenesis. <br />\nFossil fern spores, gymnosperm megaspore-membranes and pollen have also been examined. These show a similar composition to the fossil lycophyte megaspores. The constituent material of all these exines differs considerably from the sporopollenin obtained from comparable extant samples. Despite the changes in composition observed in fossilisation, differences in composition between the major groups of plants may be preserved to some extent in the fossil material. Walls of the fossil prasinophycean algal cyst Tasmanites have been examined and these show a greater similarity to fossil cuticle and algaenans than to sporopollenins.<br />\nThe effect of oxidative maceration on fossil and modern sporopollenins has also been investigated. The main influence of oxidative maceration is the removal of unsaturated carbon environments such as aromatics; this causes fossil spores to be more susceptible to oxidative maceration than the modern exines. Heating of modern exine material models the alteration of exines by diagenesis. The changes that occur on heating an extant sample to 150-225 deg C give a chemical composition that is similar to those of the fossil sporopollenins.