errata 24835

modules/m45486/index.cnxml

@@ -9,7 +9,7 @@
 </metadata>
 
 <content>
-<figure id="fig-ch11_00_01" class="splash"><media id="fs-idp78000208" alt="Photo collage shows a wolf, a cucumber-shaped protozoan, a sea sponge, a slime mold, lichen, the shore of a lake with algae and trees, a spiny lion fish, a mushroom, a sequoia tree and a bumblebee drinking nectar from a flower.">
+<figure id="fig-ch11_00_01" class="splash"><media id="fs-idp78000208" alt="Photo collage shows a wolf, a cucumber-shaped protozoan, a sea sponge, a slime mold, lichen, the shore of a lake with algae and trees, a spiny lion fish, a mushroom, a sequoia tree and a bee drinking nectar from a flower.">
 <image mime-type="image/jpeg" src="../../media/Figure_11_00_01_new.jpg" width="500"/>
 </media>
 <caption>The diversity of life on Earth is the result of evolution, a continuous process that is still occurring. (credit “wolf”: modification of work by Gary Kramer, USFWS; credit “coral”: modification of work by William Harrigan, NOAA; credit “river”: modification of work by Vojtěch Dostál; credit “protozoa”: modification of work by Sharon Franklin, Stephen Ausmus, USDA ARS; credit “fish” modification of work by Christian Mehlführer; credit “mushroom”, “bee”: modification of work by Cory Zanker; credit “tree”: modification of work by Joseph Kranak)</caption></figure><para id="fs-idm233269424">All species of living organisms—from the bacteria on our skin, to the trees in our yards, to the birds outside—evolved at some point from a different species. Although it may seem that living things today stay much the same from generation to generation, that is not the case: evolution is ongoing. Evolution is the process through which the characteristics of species change and through which new species arise.</para>

modules/m62866/index.cnxml

@@ -9,7 +9,7 @@
 </metadata>
 
 <content>
-<figure id="fig-ch19_00_01" class="splash"><media id="fs-idm102739296" alt="This photo collage shows a wolf, a cucumber-shaped protozoan, a sea sponge, a slime mold, lichen, the shore of a lake with algae and trees, a spiny lion fish, a mushroom, a sequoia, and a bumblebee drinking nectar from a flower.">
+<figure id="fig-ch19_00_01" class="splash"><media id="fs-idm102739296" alt="This photo collage shows a wolf, a cucumber-shaped protozoan, a sea sponge, a slime mold, lichen, the shore of a lake with algae and trees, a spiny lion fish, a mushroom, a sequoia, and a bee drinking nectar from a flower.">
 <image mime-type="image/jpg" src="../../media/Figure_19_00_01-f1f6.jpg" width="600"/>
 </media>
 <caption>Living things may be single-celled or complex, multicellular organisms. They may be plants, animals, fungi, bacteria, or archaea. This diversity results from evolution. (credit "wolf": modification of work by Gary Kramer; credit "coral": modification of work by William Harrigan, NOAA; credit "river": modification of work by Vojtěch Dostál; credit "fish" modification of work by Christian Mehlführer; credit "mushroom": modification of work by Cory Zanker; credit "tree": modification of work by Joseph Kranak; credit "bee": modification of work by Cory Zanker)</caption></figure>

modules/m66522/index.cnxml

@@ -8,7 +8,7 @@
 </metadata>
 
 <content>
-<figure id="fig-ch19_00_01" class="splash"><media id="fs-idm102739296" alt="This photo collage shows a wolf, a cucumber-shaped protozoan, a sea sponge, a slime mold, lichen, the shore of a lake with algae and trees, a spiny lion fish, a mushroom, a sequoia, and a bumblebee drinking nectar from a flower.">
+<figure id="fig-ch19_00_01" class="splash"><media id="fs-idm102739296" alt="This photo collage shows a wolf, a cucumber-shaped protozoan, a sea sponge, a slime mold, lichen, the shore of a lake with algae and trees, a spiny lion fish, a mushroom, a sequoia, and a bee drinking nectar from a flower.">
 <image mime-type="image/jpg" src="../../media/Figure_19_00_01-fcb8.jpg" width="600"/>
 </media>
 <caption>Living things may be single-celled or complex, multicellular organisms. They may be plants, animals, fungi, bacteria, or archaea. This diversity results from evolution. (credit "wolf": modification of work by Gary Kramer; credit "coral": modification of work by William Harrigan, NOAA; credit "river": modification of work by Vojtěch Dostál; credit "fish" modification of work by Christian Mehlführer; credit "mushroom": modification of work by Cory Zanker; credit "tree": modification of work by Joseph Kranak; credit "bee": modification of work by Cory Zanker)</caption>

modules/m66575/index.cnxml

@@ -31,7 +31,7 @@
 <para id="fs-idm120942240">Explore this <link window="new" url="https://openstax.org/l/pollinators2">website</link> for additional information on pollinators.</para></note>
 <para id="fs-idm136484096">More than 80 percent of angiosperms depend on animals for <term id="term-00002">pollination</term> (technically the transfer of pollen from the anther to the stigma). Consequently, plants have developed many adaptations to attract pollinators. With over 200,000 different plants dependent on animal pollination, the plant needs to advertise to its pollinators with some specificity. The specificity of specialized plant structures that target animals can be very surprising. It is possible, for example, to determine the general type of pollinators favored by a plant by observing the flower’s physical characteristics. Many bird or insect-pollinated flowers secrete nectar, which is a sugary liquid. They also produce both fertile pollen, for reproduction, and sterile pollen rich in nutrients for birds and insects. Many butterflies and bees can detect ultraviolet light, and flowers that attract these pollinators usually display a pattern of ultraviolet reflectance that helps them quickly locate the flower's center. In this manner, pollinating insects collect nectar while at the same time are dusted with pollen (<link target-id="fig-ch26_04_02"/>). Large, red flowers with little smell and a long funnel shape are preferred by hummingbirds, who have good color perception, a poor sense of smell, and need a strong perch. White flowers that open at night attract moths. Other animals—such as bats, lemurs, and lizards—can also act as pollinating agents. Any disruption to these interactions, such as the disappearance of bees, for example as a consequence of colony collapse disorders, can lead to disaster for agricultural industries that depend heavily on pollinated crops.</para>
 <figure id="fig-ch26_04_02">
-<media id="fs-idm117402000" alt="Photo shows a fat, yellow and black bumblebee drinking nectar from a purple and yellow flower.">
+<media id="fs-idm117402000" alt="Photo shows a fat, yellow and black bee drinking nectar from a purple and yellow flower.">
 <image mime-type="image/jpg" src="../../media/Figure_26_04_02.jpg" width="280"/>
 </media>
 <caption>Pollination. As a bee collects nectar from a flower, it is dusted by pollen, which it then disperses to other flowers. (credit: John Severns)</caption>