Tall Fescue

This image was obtained from the Smithsonian Institution. The image or its contents may be protected by international copyright laws.
MORE IMAGES
MAKE FIELD
BOOK COVER

Make Field Book Cover

Image of Tall Fescue

Create your own field book and fill it with images and object from Q?rius! When you create a field book, you can put this image on its cover.

or Sign up
0
ADD COMMENTS

EXPLORE more

TAGS

COMMENTS

Add a comment

Be the first to leave a comment!

The prickly seed of the tattered medick (Medicago laciniata) gets dispersed when it sticks to mammals or other animals
Courtesy of Tracey Slotta, USDA NRCS PLANTS Database, public domain

About Flowering Plants: Coevolution

Flowering plants are the most diverse and recent group of land plants, with ancestors dating back 130 million years. In part, they owe their diversity of more than 300,000 species to the evolution of flowers and fruits. Because they reproduce sexually, flowering plants make female and male sex cells. A flower is a fancy container for sex cells, and a fruit is a fancy container for seeds (after fertilization). Many flowers attract animal pollinators by giving nectar rewards. When a pollinator travels from flower to flower in search of nectar, it transfers pollen, enabling sexual reproduction of the plants. Flowering plants often have specific features such as flower shape and color to attract pollinators. Bright blue flowers tend to attract bees, yellows attract butterflies, and reds attract hummingbirds. Flowers pollinated at night by moths and bats are usually white with strong scents. Natural selection for showy flowers with sweet nectar has acted in tandem with natural selection for capable pollinators for millions of years in a process called coevolution. Flowering plants also owe their success to coevolution for dispersal of their seeds enclosed in fruits. For example fleshy fruits have evolved to attract humans and other animals that will eat them and drop the unharmed seeds elsewhere.

Garden onions (Allium cepa) sprouted from bulbs
Courtesy of Forest & Kim Starr, via BioLib.cz, CC-BY

About Monocots: Growth

Monocots begin their lives nourished by a single seed leaf (cotyledon). The leaf provides nutrients to the developing seed until it grows its first true leaves that can photosynthesize to make food. The true leaves are larger with parallel veins running from stem to tip. Monocots are herbaceous plants that typically don't grow large, but they are economically significant. Grasses are monocots that dominate grassland ecosystems such as prairies, and they are the source of grains such as rice, wheat, and corn that provide most of the world's food. Some monocots grow into trees sturdy enough to supply building materials, such as bamboo and palms. Many important tropical fruits, including bananas, coconuts, and pineapples, are from monocots. Some monocots in seasonal climates have evolved underground food storage organs such as bulbs to survive cold or dry conditions. The first flowers to bloom in the spring, such as daffodils and crocuses, are monocots from bulbs or bulb-like corms. Orchids are the most diverse group of monocots with over 22,000 species that are known for their beautiful flowers and relationships with insect pollinators.

The veins on the bottom of this hogweed (Heracleum sphondylium) leaf are part of its vascular system
Courtesy of JC Schou, via Biopix, CC-BY-NC

About Vascular Plants: Body Plan

In plants, the evolution of special systems to transport fluids through their bodies (vascular systems) was a successful innovation that allowed them to conquer the land. Vascular systems allowed plants to grow large and colonize a wide range of habitats from the artic to deserts and rainforests. Today, most plants we see are vascular, with cells organized into tissues specialized for transporting nutrients and fluids. These vascular tissues include xylem, which takes water and nutrients from roots to the rest of the plant. Working xylem cells are dead, just hollow tubes bounded by cell walls. Another important tissue, phloem, takes sugars (made by photosynthesis) from the leaves to the rest of the plant. Vascular plants also have advanced systems for other functions, such as support, protection, and photosynthesis. For example, leaves are a thin but complex sandwich consisting of upper layer that secretes protective wax, middle layer packed with photosynthesizing cells, and lower layer with pores (stomata) for exchanging gases.

Seeds of the goat willow (Salix caprea) are lightweight, able to float on the wind
Courtesy of Jose Hernandez, USDA NRCS PLANTS Database, public domain

About Plants (Kingdom Plantae): Feeding

Without plants, we could not survive and there would not be much diversity of life on Earth, just some tiny bacteria, algae, fungi, and tiny ocean organisms. Because of their ability to make their own food, plants are at the base of nearly every ecosystem food web. The secret of success for plants is a light-absorbing molecule (a pigment) called chlorophyll that captures the energy of sunlight by electron movements. This energy is used to make sugars from carbon dioxide and water. The leaves of plants are powerhouses for sugar manufacturing, packed with cells that contain chlorophyll. Plants uptake carbon dioxide for photosynthesis, and they release oxygen as a “waste” product, thereby supplying our atmospheric oxygen. Plants are essential for keeping carbon dioxide out of the atmosphere that would otherwise contribute to global warming. In addition plants are directly or indirectly provide the food we eat.