Practice Test: General Science (64)

First Sample Weak Response to Open-Response Item Assignment #1

Mendel studied pea plants. He demonstrated that a tall plant crossed with a short plant would create a tall plant. This means that genes are a key concept in pea plant growth. The tall gene dominates the short one. The combination of a tall and short gene is called heterozygous. If both genes are the same, either short or tall, it is called homozygous. The dominant trait of a heterozygous combination will always be the one expressed. Refer to the diagram where T (upper case) is the dominant gene for height and t (lower case) is the recessive one.

The environmental factors are meaningless in this case. Mendel proved this. This could be the second key concept.

A Punnett square key to table below TT  big T big T  = Tall Tt  big T little T  = Tall Tt  big T little T  = Tall tt  little T little T  = Short

Second Sample Weak Response to Open-Response Item Assignment #1

The potential height of a pea plant is genetic. Reaching this potential depends on environmental factors, such as the amount of sunlight, the nutrient value of the soil, and the amount of water available to the roots. Temperature of the soil and of the air are also factors.

What is unclear, of course, is epigenetic factors. For instance, are certain genes turned on or off due to environmental factors?

First Sample Strong Response to Open-Response Item Assignment #1

Key concepts related to the environmental and genetic factors that influence the growth of pea plants would be that (1) pea plants' growth is regulated by both of these factors with (2) genetics being the basis for the expected outcome and the environment holding the trump card that decides whether that outcome is realized.

All living things are governed by the concept of optimum conditions. Plant growth is a typical example. Plants require sunlight, water, proper temperature, proper soil pH p H , proper amounts of the key nutrients of phosphorous, nitrogen, and potassium as well as micronutrients such as iron, zinc, manganese, copper, etc. For each of these factors, there is a curve of optimum value. Too much or too little of something vital, and the plant's growth will not reach its full potential (see diagram). That potential is set by the genetics that the plant possesses.

When Gregor Mendel did his landmark studies of the expression of traits in pea plants, one of the traits he examined was height. He determined that a gene existed that would make a pea plant taller vs. versus  an alternate one that would leave it shorter. If a pea plant inherited the tall gene, which was dominant, it would express itself during the plant's life cycle by growing taller than other pea plants that did not possess this gene. However, Mendel had to be careful to treat all of his plants equally. If he failed to water or fertilize the potentially tall plant as well as he did the potentially shorter one, he might have ended up with two plants of equal height instead of one taller and one shorter. Regardless of the genetics, if the environment is not favorable, the expression of genes will be negatively affected.

A diagram of environmental factors versus the ratio of growth is shown. There are five zones along the environmental factors being rated from low to high. The lowest zone is the zone of intolerance, followed by the zone of physiological stress and the zone of optimum in the middle with minimal stress. However, as the environmental factor progresses higher, there is a zone of physiological stress and a zone of intolerance at the highest environmental factor. To illustrate this, overlaid over the zones is a bell curve with the ratio of growth highest in the middle of the zone of optimum and the trendline quickly tapering down to either side to intersect the x-axis at the boundary between each zone of physiological stress and zone of intolerance.

Second Sample Strong Response to Open-Response Item Assignment #1

The growth of a pea plant is affected by different environmental and genetic factors. The most important factor is the genetic information inherited from both of its parents, which controls most of its features, such as color, shape, resistance towards certain diseases, etc. Though less often, genetic mutation does occur from time to time, resulting in changes in the plant's appearances and genetic information as well.

Environment also plays an important part in here. For example, the type of climate (sunlight exposure, average temperature, precipitation, seasonal changes) and the type of soil it grows in are both important to the growth of a pea plant. Negative environmental factors, such as pollution of various kinds, will have an effect on the plant's growth as well.

Although genetics determine the key features of a plant, environment will have a huge impact on the plant's growth in a way that throughout time, plants will adapt to its environment and develop certain features that might be passed onto its future generations. In that way, environmental factors will ultimately affect the plant's genetic information and have a more profound impact on its growth and reproduction.

See scanned diagram for an example of how environmental conditions affect the growth habits of a single species of plant that grows in our region.

A diagram is shown of the growth habits of black spruce on a mountain in New Hampshire. It has a caption that reads “The same species of plant responding to different environmental conditions in its growth habits.” An incline is shown from 1,000 feet to 5,000 feet with different sized trees dotting the incline. At 1,000 feet, the black spruce are 30 to 40 feet tall. Around 3,000 feet, they are 10 to 15 feet tall. Around 4,000 feet, they are small shrubs and at 5,000 feet above sea level, they are sprawling and only grow in rock crevices.

First Sample Weak Response to Open-Response Item Assignment #2

Electrostatic forces are those forces between charged objects or surfaces. A scientific claim is that if you put a charge on an object it will stick to another object or surface. To demonstrate this, we will use some balloons and a piece of silk or fur.

Blow up the balloons and attempt to stick the balloons to the wall. They will not stick. Now rub the balloons with the silk. By doing this you are transferring a charge on the balloons and the balloons will now stick to the wall or to another person.

Second Sample Weak Response to Open-Response Item Assignment #2

Electrostatic forces will cause two objects that have some charge to interact with each other. I think that two objects of the same charge will repel each other, and that two objects of different charge will attract each other.

Use balloons as an object to rub against your head. This frees negative charges from the balloon and adds them to your head. Hold the balloon close to your head and observe what happens to your hair. Describe what is happening to your friends.

Repeat the process with a rubber rod - rubbing a felt cloth over it to negatively charge the rod. Hold the rod close to the balloon and then close to your hair. Observe what is happening and take careful notes using a chart.

Possible result - The hair may be attracted to the balloon, and repelled by the rod - the balloon may be repelled by the rod.

Noting the different behaviors (repelling/attracting) between different objects will provide evidence that "something" is different about all these objects.

First Sample Strong Response to Open-Response Item Assignment #2

Electrostatic forces are forces that exist between two charged particles. The testable scientific claim is that these forces can attract or repel. We will demonstrate that similar charges repel each other and opposite charges attract.

To investigate this claim, we will need some simple equipment. We will use a Styrofoam ball suspended from a string and then two Styrofoam balls suspended from two different strings but attached at a single pivot point. We will also need a glass rod, rubber rod, a piece of silk and a piece of fur.

Take the single Styrofoam ball suspended from a string and then take the rubber rod and rub it with the piece of fur. Touch the rubber rod to the Styrofoam ball. The charge on the rod will be transferred to the ball. Then rub the rod again with the fur. A similar charge will be placed on the rod. Now bring the rod close to the Styrofoam ball. The ball will be repelled by the rod showing that similar charges repel one another. Now rub the glass rod with the silk. When you now bring the glass rod toward the Styrofoam ball, the ball will be attracted toward the rod showing that opposite charges attract.

Now take the two attached at a pivot point. Take either the glass rod rubbed with the silk or the rubber rod rubbed with the fur and bring either one toward the Styrofoam balls. The charge will be transferred to the balls, and the balls will separate from each other. This also shows that similar charges repel from one another.

By taking either rod and rubbing it with the respective cloth we can put a charge on the rod and by having it come in contact with either Styrofoam ball, we can transfer the charge to the ball and then demonstrate how the charges can be either attracted or repelled, supporting the tested claim.

Second Sample Strong Response to Open-Response Item Assignment #2

Using a Wimshurst machine, we will demonstrate that charges can be transferred from metal plates to solid balls via wire brushes. Then the charge can be transferred to either people or discharged as the two metal balls come close to each other.

Turn the crank slowly on the machine, keeping the two metal balls on the arms about 10 cm apart from each other. After a few minutes, stop turning the crank and then slowly bring the balls close to each other. Opposite charges will have built up on each ball, and as the balls come close to each other, a spark will occur from one ball to the other. The opposite charges are attracted to each other.

Now move the arms with the balls much farther apart, about 1 meter, and turn the crank harder. After a few minutes, have the students in the class hold hands with each other, forming a chain. Now have the end students hold on to each of the balls. The balls will discharge through the students and each will feel a slight tingling sensation.

This will demonstrate that a charge can be transferred from the metal plates onto the balls and then onto the students or into the air. One ball will be positively charged and the other negatively charged. The spark generated when the two balls come close to each other or the tingling sensation felt when the students touch both balls shows that opposite charges attract each other. If this is true, then we can conclude that like charges will repel.