The Evolution of Plants

During the Triassic and Jurassic, the forest canopy was dominated by giant conifers of the Araucariaceae and Cheirolepidiaceae families, reaching 30 to 60 meters. Below, cycads, bennettitales, and ginkgoales formed the mid-story, and the ground was covered by ferns, mosses, and horsetails. There were no grasses, flowers, or fruits. This landscape persisted for over 100 million years.

Sauropod diets depended on these plants. Carbon isotope analyses from tooth enamel (Morrison Formation, USA) indicate that Brachiosaurus reached the araucaria canopy, while Diplodocus grazed on ground-level ferns. Laboratory tests (Hummel et al., 2008) showed that Araucaria foliage and horsetails produce energy comparable to modern fodder, making the gigantism of these animals viable.

Notable fossil sites

Silicified cone of Araucaria mirabilis, Middle Jurassic (~160 Ma), Cerro Cuadrado, Patagonia. Extraordinary cellular preservation with intact embryos. Wikimedia Commons.

Jurassic forest vs. modern

Bennettitales were an order of gymnosperm plants that lived for nearly 170 million years. Externally resembling modern cycads, with robust trunks and pinnate leaves, they concealed a crucial difference: their reproductive organs. Some species, such as Williamsonia and Cycadeoidea, developed flower-like structures with petaloid bracts and male and female organs united in the same reproductive unit.

The decline of Bennettitales is closely tied to the rise of angiosperms. As flowering plants diversified from ~100 Ma onward, they conquered the ecological niches previously occupied by Bennettitales. With faster growth rates and mutualistic relationships with pollinators, angiosperms held a decisive competitive advantage. Bennettitales disappeared at the K-Pg boundary (66 Ma), possibly already in severe decline before the Chicxulub impact.

Convergent evolution

The former "Anthophyte Hypothesis" proposed that Bennettitales were direct ancestors of flowering plants. Modern phylogenetic analyses refuted this idea: Bennettitales are closer to cycads and ginkgos, not to angiosperms. The floral resemblance is purely convergent, which makes the group even more fascinating.

Two families

The earliest angiosperm fossil records include pollen grains from ~136 million years ago found in Israel, the aquatic plant Montsechia vidalii (~130 Ma, Spain), and Archaefructus sinensis (~125 Ma, China). In just 30 million years, they went from marginal elements to dominants in terrestrial ecosystems, one of the fastest ecological transitions in history.

The impact on fauna was profound. The diversification of ornithischian dinosaurs in the Late Cretaceous coincides with angiosperm dominance. Hadrosaurs ("duck-billed" dinosaurs) developed complex dental batteries, with hundreds of compacted teeth forming grinding surfaces to process the tough, silica-rich leaves of the new plants.

Earliest fossils

Decisive adaptations

The earliest evidence of insect pollination dates back to ~99 million years ago, preserved in Burmese amber (Myanmar). Fossils of thrips (Gymnopollisthrips minor) carrying pollen grains and beetles (Cretoparacucujus cycadophilus) associated with cycad pollen demonstrate that entomophilous pollination arose even before the great angiosperm diversification. Long-proboscid flies also appear in this period.

Insect pollination dramatically accelerated angiosperm diversification. By enabling reproductive isolation and rapid speciation, each flower-pollinator pair could diverge independently. Molecular clock studies (Magallón et al., 2015) show that the major angiosperm lineages (rosids, asterids) diversified between 115 and 90 Ma, coinciding with pollinator diversification.

Progression of pollination syndromes

Key evidence: Burmese amber (~99 Ma)

Multiple insect groups preserved carrying pollen: thrips, beetles, flies. Myanmar amber is Cenomanian in age and also contains one of the oldest flowers preserved in resin, Micropetasos burmensis, with structures indicating insect pollination.

First identified by Tschudy et al. (1984) in rocks from the Hell Creek Formation (Montana, USA), the "fern spike" consists of an abrupt increase in fern spores in the palynological record: from about 25% to over 70 to 100% of palynomorphs, just above the iridium layer deposited by the Chicxulub impact. Vajda and Bercovici (2014) confirmed the pattern on a global scale, documenting equivalent fern spikes in New Zealand and Japan.

The K-Pg fern spike lasted between 1,000 and 10,000 years, an extremely brief geological interval that reveals the scale of the devastation. Analogous phenomena were recorded after the end-Permian extinction (~252 Ma), with lycophytes dominating the record, and at the end of the Triassic (~201 Ma). Full recovery of diversified forests took between 100,000 and 1,000,000 years.

Why do ferns dominate after catastrophes?

Post-impact recovery sequence

Modern analogues: after the eruption of Krakatoa (1883) and Mount St. Helens (1980), ferns were among the first plants to establish themselves on volcanic ash.

Origin of grasses

Molecular estimates place the origin of the Poaceae family between 80 and 100 million years ago, still in the Cretaceous period. The oldest grass fossil was found in Myanmar amber (~100 Ma). The first grasses were small understory plants, growing in the shade of conifers, ferns, and angiosperms that dominated the Mesozoic landscape.

Dinosaurs ate grass

In 2005, Prasad and colleagues published a discovery in Science that shook paleontology: phytoliths from at least five different types of grasses were found in titanosaur coprolites from the Lameta Formation, central India. Giant sauropods of the Late Cretaceous were already including grasses in their diet. Grasses were not dominant, but they were part of the available vegetation.

Grasses survive the extinction

The Chicxulub impact killed the non-avian dinosaurs, but grasses made it through the catastrophe. As herbaceous plants with basal meristems (growth points close to the ground), they were more resistant to destruction than trees. This same trait makes grasses resistant to fire, grazing, and drought.

Silent diversification

In the warm, humid world of the Paleocene and Eocene, forests dominated. Grasses remained minor components of the vegetation for tens of millions of years, slowly diversifying in understories and along riverbanks. The Bambusoideae and Ehrhartoideae subfamilies (which include rice) differentiated during this period. The phytolith record shows a gradual increase in grass presence.

First open grasslands

Global cooling after the Antarctic glaciation (~33.9 Ma) and falling CO₂ levels created drier, more seasonal conditions. Forests retreated. For the first time, open habitats dominated by grasses began to appear in parts of South America and Africa. The phytolith record shows the transition from forest vegetation to mixed.

The Grass Revolution

The great moment. Global cooling, the drop in atmospheric CO₂ below ~500-800 ppm, and increased seasonality created ideal conditions for the explosion of C4 grasses. Open grasslands replaced forests across vast continental areas of Africa, the Americas, and Asia. Fauna was transformed: horses evolved from three-toed forest animals to single-hoofed grazers with hypsodont teeth (high-crowned, resistant to silica wear from grasses). Ruminants diversified. Swift predators thrived on the open plains. It was the greatest restructuring of terrestrial ecosystems since the extinction of the dinosaurs.

The dominant biome

Grasses cover approximately 40% of the Earth's land surface (excluding Greenland and Antarctica). The Poaceae family has about 12,000 species. Wheat, rice, corn, sorghum, sugarcane, and rye are all grasses: they sustain the caloric foundation of human civilization. Natural grasslands are now considered the most threatened biome on the planet, with over 70% already converted to agriculture.

What are phytoliths?

Phytoliths are microscopic silica (SiO₂) structures that form inside plant cells. Each grass subfamily produces phytoliths with distinct diagnostic shapes: bilobate, saddle-shaped, cross-shaped. When the plant dies or is digested, phytoliths resist decomposition and remain in the soil, sediments, or coprolites for millions of years. They are like botanical "fingerprints" that survive geological time.

What they found

In the coprolites from the Lameta Formation (central India, ~67 Ma), Prasad et al. identified phytoliths from at least five distinct grass lineages, including representatives of the Bambusoideae and Ehrhartoideae subfamilies (the rice subfamily). The diversity found indicates that the family was already well differentiated before the extinction of the dinosaurs. In 2011, a second study by the same group, published in Nature Communications, demonstrated that the rice tribe (Oryzeae) had already diversified in the Late Cretaceous.

Before vs. after the discovery

Grass phytoliths observed under scanning electron microscope (SEM). These silica structures are preserved for millions of years and allow identification of grass subfamilies in fossil coprolites. Wikimedia Commons (CC BY-SA 3.0)

Elongated grass phytoliths under optical microscope. The diagnostic shapes (bilobate, saddle, cross, elongated) vary by subfamily, functioning as botanical "fingerprints." Wikimedia Commons (CC BY-SA 3.0)