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<span><span>2. Decomposition A. The breakdown of organic matter, such as dead animals.</span></span><span />
<span>3. Fossil Fuels C. Oil and coal produced from compacted decomposed organic matter</span>
<span /><span><span>4. Photosynthesis <span>B. Recycles carbon from carbon dioxide into glucose</span></span></span>
<span><span><span>sry that's all ik :( (I may have mixed up photo synthesis and decomposition with the other words by accident)</span></span></span>
<span><span><span>try searching the rest on google </span></span>
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Answer:
"You have to believe the exercise works before you try it" would be the pseudoscientific claim.
Answer:
The correct option is B. The offspring will inherit neither the genotype nor the phenotype change.
Explanation:
Any changes which occur in the DNA sequence of a person are termed as mutations.
Mutations will only be transferred to offsprings if the mutated gene or sequence gets incorporated into the genome of the mutated person.
In the above scenario, the mutation is just changing the person's phenotype and it has not been incorporated in the genotype of the affected person. Hence, the offsprings will not inherit the mutation, nether in their genotype nor the phenotype.
Air that moves horizontally between high and low pressure zones makes wind. The greater the pressure difference between the pressure zones the faster the wind moves. Convection in the atmosphere creates the planet's weather.
Hope that helps:)
Answer:
According to Hardy Weinberg equilibrium, allele frequencies in a population remain constant given that there is no evolutionary force acting on the population. In the given case the situation is not ideal since the owls are acting like an evolutionary force for the mice population.
Darker mice will be able to camouflage better in dark soil and hence will be less targeted by the owls. As a result lighter coloured mice will decrease in numbers which will eventually increase the frequency of dark allele in the population, violating the Hardy Weinberg equilibrium.