The two factors that create the difference between the temperate forest biome and the taiga biome are as follows:
A biome may be characterized as a very large ecosystem that is consistently running in nature in an unmanaged way. In more simple words, it is defined as a very large area that is characterized by a particular type of vegetation. Some examples of biome may include tropical rainforests, coral reefs, grasslands, etc.
Taiga biomes are generally thick forests. Coniferous trees, such as spruce, pine, and fir, are common. These trees have needles instead of broad leaves, and their seeds grow inside protective, woody cones.
While temperate forests have deciduous trees which lose their leaves in winter, conifers never lose their needles. All such differences are created by numerous factors but temperature and precipitation are the most potent ones.
Therefore, temperature and precipitation are the two factors that create the difference between the temperate forest biome and the taiga biome.
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The temperate forest biome covers latitudes ranging approximately from the southern United States to southern Canada, while the taiga biome, also known as boreal forest, extends from the latitude of southern Canada to about 60 degrees north latitude. (see References 1, References 3) Thus, these two biomes are adjacent, which explains the many similarities between taiga and northern temperate forests. Both biomes have four distinct seasons, but the temperate forest climates cover a much wider range of temperatures and precipitation patterns. Taiga, in contrast, is reliably cold: most of the precipitation falls as snow, winters are severe and the growing season is short -- about 130 days compared to 140 to 200 days for temperate forests.
A)seafloor spreading at mid-ocean ridges
B)reversing paleomagnetism in rocks on the ocean floor
C)evidence of ancient tropical swamps in cold regions of North America
D)
a seafloor that was geologically active with earthquakes, volcanoes, and mountain chains
Answer:
C. Evidence of ancient tropical swamps in cold regions of North America
Explanation:
I took the test here is my proof that this is correct (Hope I helped):
100%
25%
75%
50%
Answer:
50%
Explanation:
It's not exactly 50%, but it's close to it
The actual percentage is .493333 CONT.
Answer:
50%
Explanation:
The chance that a fetus that will be born male is 50%
The chance that a fetus that will be born female is 50%
mRNA, ribosome, tRNA and aminoacyl-tRNA syntheatases are needed for translation.
Explanation:
In the translation process message is decoded into a polypeptide. Through interlinking of peptide bond amino acid covalently strung together. In this process each amino acid has a carboxyl and amino group.
Ribosome is catalysed for this reaction and generate the one water molecule. It is a complex macromolecule. It exists in the prokaryotes. Gene make the protein through the process of translation. In translation process mRNA is decoded and resultant protein is built.
Answer:
mRNA
Ribosome
tRNA
codons
Explanation:
Photosynthesis makes the glucose that is used in cellular respiration to make ATP. The glucose is then turned back into carbon dioxide, which is used in photosynthesis. While water is broken down to form oxygen during photosynthesis, in cellular respiration oxygen is combined with hydrogen to form water.
Photosynthesis and cellular respiration are two interdependent processes. Photosynthesis uses carbon dioxide and water to produce carbohydrates and oxygen, while cellular respiration uses these carbohydrates to produce energy, carbon dioxide, and water. They form a cyclical biological harmony vital to life.
Photosynthesis and cellular respiration are two fundamental processes in the carbon cycle that share reciprocal reactants and products. In photosynthesis, plants absorb light energy to build carbohydrates in chloroplasts, using carbon dioxide and water. The resulting byproduct of this process is oxygen. On the other hand, cellular respiration occurs in the cytoplasm and mitochondria, where organisms metabolize these carbohydrates to produce energy, in the process releasing carbon dioxide and water. Both processes use electron transport chains to capture the energy necessary to drive other reactions.
Thus, photosynthesis and cellular respiration are linked in a cyclical biological harmony; they provide the life-sustaining energy that originates millions of miles away in the sun. Photosynthesis produces the carbohydrates needed for cellular respiration, and cellular respiration releases the carbon dioxide required for photosynthesis, creating an interdependent cycle vital to most forms of life on Earth.
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