When evaluating data, why is it better to make a graph instead of just looking at the raw data in a table?

Final answer:

An ice-skater who pulls her arms in will spin faster due to the conservation of angular momentum, as a reduction in her moment of inertia results in an increased rotation speed to keep the angular momentum unchanged.

Explanation:

Because angular momentum is conserved, an ice-skater who throws her arms out will experience a change in their rotation speed when altering their body's configuration. When a figure skater on ice extends her arms while spinning, she has a certain angular momentum, which depends on her rotation speed and the distribution of her mass—or her moment of inertia. With arms extended, her moment of inertia is greater. If she pulls her arms in, she reduces her moment of inertia, but because no external torque is acting on her, her angular momentum must stay constant. To maintain the same angular momentum with a smaller moment of inertia, her rotation speed—or angular velocity—must increase. Therefore, when an ice skater pulls in her arms, she spins faster; this is a classic demonstration of the conservation of angular momentum.

The formula for angular momentum (l) is defined as l = mvR, where m is the mass, v is the linear speed, and R is the radius of the orbit or the distance from the axis of rotation. When the skater pulls her arms inward, 'R' decreases, and since mass ('m') remains unchanged, the speed ('v') must increase for the angular momentum to stay conserved. This result in an increased rate of spin, which is also seen as an increase in rotational kinetic energy due to the work done by the skater to pull her arms closer to her body.

Answer;

B. Without good stability, athletes are too clumsy to perform well.

Explanation;

Stability refers to the resistance to both linear and angular acceleration, or resistance to disruption of equilibrium.

Developing and enhancing core strength and stability helps athletes to maximize their power output and enhance game day performance. Additionally, Improving core strength and stability can also help athletes reduce their risk of injury.

Stability is an important skill for an athlete because without good stability, athletes are too clumsy to perform well.

Option B is correct

Stability is the ability of an athlete retain controls for more than the average distance of a movement, This does not mean an athlete will no be displace but the ability to regain shape is stability

Therefore, without good stability, athletes are too clumsy to perform well.

Option B is correct

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Final answer:

The behavior (rising or falling) of a wooden block in oil based on buoyancy and calculating the wood's density, which is found to be 600 kg/m³ based on its specific gravity.

Explanation:

Applying Archimedes' principle, which states that the buoyant force on a submerged object is equal to the weight of the fluid displaced by the object, can solve this problem. Since the block is submerged in oil with a specific gravity (sg) of 0.8, and has an attached aluminum plate, the overall density and buoyancy of the system are affected, leading to a complex calculation that incorporates the densities of the wood, aluminum, and oil.

The block will rise if its combined density (wood and aluminum) is less than that of the surrounding oil. Since wood has a lower specific gravity than oil, it tends to float, but the attached aluminum plate, with a specific weight of 168 lb/ft³, increases the system's density. Whether it rises or falls will depend on the overall density compared to the oil's density.

The density of the wood can be derived from its specific gravity. The specific gravity is the ratio of the density of the wood to the density of water (1000 kg/m³). Therefore, a specific gravity of 0.6 indicates the wood's density is 600 kg/m³.

The widely accepted theory about global climate change is :

The formation of CO₂ by the mixture of carbon and oxygen is a widely accepted theory because of its effect on global climate change. the predictions regarding this theory includes some positives and negatives.

some of the positive predictions is :

some negative predictions include

Hence we can conclude that The widely accepted theory about global climate change is The formation of CO₂ by carbon and oxygen.

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A boat has a mass of 6800 kg. its engines generate a drive force of 4100 n, due west, while the wind exerts a force of 830 n, due east, and the water exerts a resistive force of 1200 n due east, the boat's acceleration is approximately [tex]\(0.301 \, \text{m/s}^2\)[/tex] due west.

Newton's second rule of motion, which states that the net force exerted on an object is equal to the product of its mass and acceleration, can be used to determine the boat's acceleration:

[tex]\[F_{\text{net}} = m \cdot a\][/tex]

Given:

Mass (m) = 6800 kg

Engine force ([tex]\(F_{\text{engine}}\)[/tex]) = 4100 N (due west)

Wind force ([tex]\(F_{\text{wind}}\)[/tex]) = 830 N (due east)

Water resistive force ([tex]\(F_{\text{water}}\)[/tex]) = 1200 N (due east)

Net force ([tex]\(F_{\text{net}}\)[/tex]) is the vector sum of all the forces acting on the boat:

[tex]\[F_{\text{net}} = F_{\text{engine}} + F_{\text{wind}} + F_{\text{water}}\][/tex]

Convert the eastward forces to negative values since they are acting in the opposite direction:

[tex]\[F_{\text{net}} = 4100 \, \text{N} - 830 \, \text{N} - 1200 \, \text{N}\][/tex]

Calculate [tex]\(F_{\text{net}}\)[/tex]:

[tex]\[F_{\text{net}} = 2050 \, \text{N}\][/tex]

Now we can use Newton's second law to find the acceleration (a):

[tex]\[F_{\text{net}} = m \cdot a\][/tex]

[tex]\[a = \dfrac{F_{\text{net}}}{m}\][/tex]

Plug in the values:

[tex]\[a = \dfrac{2050 \, \text{N}}{6800 \, \text{kg}}\][/tex]

Calculate the magnitude of the acceleration:

[tex]\[a \approx 0.301 \, \text{m/s}^2\][/tex]

Thus, the boat's acceleration is approximately [tex]\(0.301 \, \text{m/s}^2\)[/tex] due west.

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The magnitude of the boat's acceleration is approximately 0.304 m/s² towards the west.

To find the magnitude and direction of the boat's acceleration, we need to consider the net force acting on the boat. The net force is equal to the sum of all the forces acting on the boat. In this case, we have a drive force of 4100 N due west, a wind force of 830 N due east, and a resistive force of 1200 N due east. Using Newton's second law, we can calculate the net force:

Net force = (4100 N) - (830 N + 1200 N) = 4100 N - 2030 N = 2070 N

The acceleration of the boat can be calculated using the formula:

Acceleration = Net force / Mass = 2070 N / 6800 kg ≈ 0.304 m/s²

The magnitude of the boat's acceleration is approximately 0.304 m/s² and the direction is towards the west.

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The forces acting on the skydiver is downward force due to his own weight,  and drag force acting upwards due to air resistance.

At a constant speed, the upward acceleration of the skydiver is zero. The downward acceleration is equal to acceleration due to gravity. The upward force is equal to downward force.

The sketch of the forces acting on the skydiver is presented below using simple diagram;

                                 ↑ N

                                 Ф

                                  ↓ W

Thus, the forces acting forces acting on the skydiver is downward force due to his own weight,  and drag force acting upwards due to air resistance.

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Answer;

The distance from the sun to Neptune is about the same as the distance from Neptune to the next closest star, Proxima Centauri

Explanation;

When a planet like earth is closer to the sun the heat of the sunlight warms the surface of the planet hence,a planet like Neptune is far away from sun, the sunlight can't reach the planet and it's surface becomes cold so,the distance of the sun and planet is the main factor effecting the temperature.

Final answer:

The periodic table symbolizes the relationship between chemistry and physics by organizing elements based on their atomic numbers and grouping them by shared properties, influencing their chemical reactivity and physical states.

Explanation:

The relationship between chemistry and physics can be explored through the study of the periodic table, a fundamental tool in the chemical sciences. The periodic table not only lists elements by increasing atomic number but also groups them by shared physical and chemical properties. For example, elements that are gases, liquids, or solids at room temperature can be predicted based on their placement in the periodic table. Similarly, an element's chemical reactivity is indicated by its grouping, which suggests its tendency to combine and form chemical bonds. The table, conceptualized by Dmitri Mendeleev, reflects the periodic trends in electron configuration which underpin both the chemical behaviors and physical properties, such as electrical conductivity. Indeed, the understanding of such properties has been instrumental in technical advancements, such as the use of silicon in electronics due to its semiconductor properties. Thus, the periodic table encapsulates the core principles bridging chemistry and physics.

Answer: POSITIVE

Explanation:

A diver having mass m climbs up the diving board.
We know that Gravitational potential energy is given as PEG=mgΔh

What changes is his Gravitational potential energy due to change of height Δh with reference to the ground/water level.
While standing on the diving board his velocity is zero. As such kinetic energy is also zero.

Once he jumps off the springboard we see he gets additional energy from the springboard and falls down under action of gravity g. Due to decrease of height above the ground level Gravitational potential energy decreases and gets converted in to his kinetic energy. 1/2mv2.

While in air he encounters air resistance. Some of his energy is spent in overcoming this resistance. Gets converted in to kinetic and thermal energy of surrounding air and his body.

Once diver reaches the water, we see water splashing and hear noise of splash. Thereafter the diver comes to rest. Now his potential energy becomes zero. And converted kinetic energy has been converted in to kinetic energy, heat energy and sound energy of water.

As such energy transformation equation looks like

Gravitational PE+Elastic PE of springboard→Kinetic energy of air and water+Sound energy of splash+thermal energy

Final answer:

The diver gains potential energy as they climb the diving board, which converts into kinetic energy as they dive towards the water. The chemical energy from the diver's body is used for the mechanical work of climbing. The potential energy of the diving board increases when the diver steps on it and then returns to its initial state after the dive.

Explanation:

As a diver climbs up to a diving board, their potential energy increases because potential energy is related to the height of an object above a reference point, in this case, the water level. This potential energy is a result of gravitational force acting on the diver. The chemical energy from the diver's muscles is converted to mechanical work, enabling them to climb to the top of the diving platform.

Once the diver steps off the diving board, the stored potential energy begins to convert into kinetic energy, which is the energy of movement. As the diver falls towards the water, their speed and, consequently, their kinetic energy increase, while their potential energy decreases. When the diver's feet leave the diving board, the potential energy is at its maximum, and as they fall, it decreases to zero upon impact with the water when kinetic energy is at its peak.

Should the diving board exert a conservative force with negligible internal friction, the potential energy of the board itself would be momentarily increased as the diver steps onto it and compresses it downwards, storing energy in its elastic deformation. After the diver leaves the board, this energy is released, returning the diving board to its initial state.

Final answer:

The mass of the meteoroid in standard notation is 12,400,000 kilograms, which is obtained by moving the decimal point 7 places to the right in the given scientific notation 1.24 × 10⁷ kilograms.

Explanation:

The mass of a meteoroid was found to be 1.24 × 10⁷ kilograms. To write this mass in standard notation, we simply translate the exponential notation into a long form number. This means we shift the decimal place to the right as many times as indicated by the exponent. Here, the exponent is 7, so we move the decimal 7 places to the right.

Starting with 1.24, we would add six zeros after the 24 to fill in the places as we move the decimal: 12,400,000 kilograms. This is the mass of the meteoroid in standard notation.

The car's velocity to be 2.4 m/s, and the distance covered in the first 4 seconds to be 4.8 meters.

From the given parameters and the provided graph, we're tasked with determining the velocity of a car and the distance it covers within a specific time interval. The total distance traveled by the car (S) is 12 meters, and the total time taken is 8 seconds. To find the velocity (V), we use the formula for the area of a trapezium.

Firstly, using the area of a trapezium formula, where S = 1/2 (a + b) * V, with a and b representing the parallel sides of the trapezium formed by the graph:

Given that a = 2 and b = 8, we substitute these values into the formula:

12 = 1/2(2 + 8) * V

24 = 10V

V = 24/10

V = 2.4 m/s

Thus, the velocity of the car is calculated to be 2.4 m/s.

Next, within the first 4 seconds, the shape of the distance covered by the car forms a triangle on the graph. Utilizing the formula for the area of a triangle, which is 1/2 * base * height, where the base is the time (4s) and the height is the speed (V = 2.4 m/s):

S = 1/2 * 4 * 2.4

S = 4.8 m

Hence, the distance covered by the car within the first 4 seconds of its motion is 4.8 meters.

In summary, by calculating the velocity using the area of a trapezium and determining the distance covered within a specific time interval using the area of a triangle, we find the car's velocity to be 2.4 m/s, and the distance covered in the first 4 seconds to be 4.8 meters.

The question probable may be;

A car in stop-and-go traffic starts at rest, moves forward 12 m in 8.0 s, then comes to rest again. The velocity-versus-time plot for this car is given in the figure. What distance does the car cover in the first 4.0 seconds of its motion?

Final answer:

The average force exerted by the ball on the glove is approximately 857 N.

Explanation:

To calculate the average force exerted by the ball on the glove, we can use the equation:

F = m × Δv / Δt

where F is the average force, m is the mass of the ball, Δv is the change in velocity, and Δt is the time taken.

In this case, the mass of the ball is given as 145g, which is equal to 0.145 kg. The change in velocity of the ball is given as 40 m/s, since it travels from an initial speed of 40 m/s to a final speed of 0 m/s when caught. The time taken is calculated by converting the distance the glove moves to meters (27 cm = 0.27 m) and dividing it by the final speed of the ball. Therefore, Δt = 0.27 m / 40 m/s = 0.00675 s.

Now we can substitute the given values into the formula to find the average force:

F = (0.145 kg × 40 m/s) / 0.00675 s ≈ 857 N

Therefore, the average force exerted by the ball on the glove is approximately 857 N.

F = ma

A = F / m = 1 x 10^1 + (2.5) (9.3) / 2.5 = 1 x 10^1 + 24.5 /2.5 = 34.5 / 2.5 = 13.8 m/s^2

By using kinematic equation, V = 4 + ak

0 = 6.7 – 13.8 t

13.8t = 6.7

T = 6.7 / 13.8 = 0.4855 sec