On a small island, scientists observed and graphed changes in wolf and moose populations. From 1965 to 1970, which pattern did scientists observe?
If your question is in 8th SOL test then:
A drop in wolf population the dotted line goes down and increase in mousse population the full line goes up.
You can also in google paste:
On a small island, scientists observed and graphed changes in wolf and moose populations. From 1965 to 1970, which pattern did scientists observe?
When you see list of results click on:
8th Grade KEY 2015 SOL released test
If that is your test you can check your answers.
Oh, are you ready for some scientifically hilarious fun? Well, during that period, the scientists observed a game of population tag, but with a twist! The wolf population was like, "Tag, you're it!" and chased after the moose population, trying to catch up. But the sneaky moose were like, "No way, furballs!" and they managed to outrun the hungry wolves. So, in short, the wolf population increased, while the moose population took a swift little dip. It was like a real-life game of hide-and-seek, with claws and antlers involved. What a wild time!
To accurately answer your question on the observed pattern in wolf and moose populations from 1965 to 1970, I would need the specific data or information provided by the scientists on the small island. However, I can offer you a general understanding of possible patterns that scientists might observe during that period.
1. Stable Pattern: The wolf and moose populations remained relatively constant or showed minor fluctuations around an equilibrium point. This pattern suggests a balanced predator-prey relationship, indicating that the population sizes were stable and sustainable.
2. Cyclic Pattern: There might have been regular cycles of increase and decrease in wolf and moose populations. Such patterns could indicate predator-prey interactions, where predators (wolves) increase in numbers, leading to a subsequent rise in prey (moose) populations. As moose populations increase, it could result in more food availability for wolves, leading to a rise in wolf populations. This pattern tends to repeat in a cyclic manner.
3. Lagged Cycle Pattern: Another possible pattern could be a lagged cycle, where the wolf and moose populations cycle, but there is a time delay between the peaks and troughs of both populations. This could suggest that the impact of changes in one population takes time to affect the other population, resulting in a delayed response.
4. Random Fluctuations: In some cases, the population patterns may not show a clear trend or predictable cycles. Population sizes might fluctuate randomly due to various factors like environmental conditions, resource availability, or other unknown factors.
Remember that the actual pattern observed by scientists would significantly depend on the specific data collected and analyzed during that time on the island.
To determine the pattern of changes in wolf and moose populations on a small island from 1965 to 1970, you would need access to the data or the graph created by the scientists. Without access to the specific information, it is impossible to provide an accurate answer about the observed pattern during that specific time period.
However, I can explain a general approach you can follow to analyze such data:
1. Obtain the data or graph: Look for scientific studies, reports, or publications that might have documented the population trends of wolves and moose on the specific island during the given time range. This information might be available in ecological studies, research papers, or databases.
2. Examine the population data: Once you have access to the data, examine the population numbers of wolves and moose for each year from 1965 to 1970. Take note of the numeric values and any other relevant information such as population densities, habitat changes, or environmental factors.
3. Analyze the population trends: Plot the data on a graph, with the x-axis representing the years from 1965 to 1970 and the y-axis representing the population numbers or densities of wolves and moose. Look for any trends, such as increases, decreases, or fluctuations in the population sizes over time.
4. Interpret the findings: Based on the graph or data analysis, observe whether there are any noticeable patterns. Determine if there is any correlation or relationship between the wolf and moose populations during the given period. Consider factors such as predator-prey dynamics, competition for resources, or other ecological interactions that might influence population fluctuations.
Remember that the observed pattern can vary depending on the specific island, the available data, and the ecological dynamics at play. Therefore, it is essential to consider the actual data or research findings to provide an accurate answer regarding the pattern observed by the scientists during that time period.