One of the Pea plants mates more than the others.
an equilibrium point at which, if either population changes, the population sizes will diverge from, rather than return to, the equilibrium point; a combination of population sizes at which the two populations could coexist, but when the combination changed, no impetus exists to return to the equilibrium population sizes.
The rat population is not in Hardy-Weinberg equilibrium due to factors such as non-random mating and gene flow. Non-random mating occurs when certain traits influence mate selection, leading to an uneven distribution of alleles. Additionally, gene flow from neighboring populations can introduce new alleles or change allele frequencies, disrupting the equilibrium. These dynamics prevent the population from maintaining constant allele frequencies over generations.
The two types of equilibrium are static equilibrium and dynamic equilibrium. Static equilibrium is when an object is at rest, while dynamic equilibrium is when an object is moving at a constant velocity with no acceleration. Static equilibrium involves balanced forces in all directions, while dynamic equilibrium involves balanced forces with movement.
In a population in Hardy-Weinberg equilibrium, the number of heterozygotes is maximized when the two alleles are at equal frequencies, specifically when the frequency of each allele (p and q) is 0.5. Under these conditions, the frequency of heterozygotes (2pq) reaches its peak value of 0.5, meaning half of the population will be heterozygous. This scenario reflects an optimal genetic diversity within the population.
It will take a short time to reach equilibrium It will take a long time to reach equilibrium The equilibrium lies to the right The equilibrium lies to the left Two of these One of those answers...
an equilibrium point at which, if either population changes, the population sizes will diverge from, rather than return to, the equilibrium point; a combination of population sizes at which the two populations could coexist, but when the combination changed, no impetus exists to return to the equilibrium population sizes.
The rat population is not in Hardy-Weinberg equilibrium due to factors such as non-random mating and gene flow. Non-random mating occurs when certain traits influence mate selection, leading to an uneven distribution of alleles. Additionally, gene flow from neighboring populations can introduce new alleles or change allele frequencies, disrupting the equilibrium. These dynamics prevent the population from maintaining constant allele frequencies over generations.
Hydrostatic and Equilibrium
Contraseptives and exponential birthrates can be two reasons for overpopulation
diseases and wars
The two types of equilibrium are static equilibrium and dynamic equilibrium. Static equilibrium is when an object is at rest, while dynamic equilibrium is when an object is moving at a constant velocity with no acceleration. Static equilibrium involves balanced forces in all directions, while dynamic equilibrium involves balanced forces with movement.
mating must happen randomly
In a population in Hardy-Weinberg equilibrium, the number of heterozygotes is maximized when the two alleles are at equal frequencies, specifically when the frequency of each allele (p and q) is 0.5. Under these conditions, the frequency of heterozygotes (2pq) reaches its peak value of 0.5, meaning half of the population will be heterozygous. This scenario reflects an optimal genetic diversity within the population.
The property that determines if two objects are in a state of thermal equilibrium is the temperature. In thermal equilibrium, the temperatures of the two objects are equal, and there is no net heat transfer between them.
The two kinds of equilibrium are the folowing:Physical, which is an open system, and the rate of substances in, equals the rate of substances out.The other equilibrium is chemical equilibrium, which is a closed system, and the rate of the forward reaction equals the rate of the reverse reaction.
There are two reasons for water shortage, one due to wastage, and two over population and not enough pipes.
The zeroth law of thermodynamics pertains to the concept of thermal equilibrium between two systems. It states that if two systems are each in thermal equilibrium with a third system, then they are in thermal equilibrium with each other. This law establishes the transitivity of thermal equilibrium relationships.