A completely submerged object always displaces its own

To go through the basket, the ball needs to be thrown with an initial speed of approximately 25.2 m/s.

The initial speed at which the ball needs to be thrown in order to go through the basket can be determined using the equations of projectile motion. We can break the initial velocity of the ball into its horizontal and vertical components. The horizontal component will determine the distance the ball will travel, and the vertical component will determine the height at which the ball will pass through the basket.

Using the given information, including the angle at which the ball is released and the height of the basket, we can calculate the initial speed of the ball using trigonometry and projectile motion equations. The initial speed required for the ball to go through the basket is the magnitude of the total initial velocity, which is the vector sum of the horizontal and vertical components.

The initial speed required for the ball to go through the basket is approximately 25.2 m/s.

The magnitude of the normal force, fn, for a block on a horizontal rigid surface with a gravitational force fg of 40 N is equal to the gravitational force, making fn also 40 N.

The magnitude of the normal force, fn, acting on a block on a horizontal surface is equal to the weight of the block when the surface is rigid and there are no other vertical forces except gravity. If we denote the gravitational force as fg, which in this case is 40 N, and given that there are no additional vertical forces and the surface is horizontal, the normal force will balance the gravitational force. Therefore, we have  fn = fg, so the normal force fn is also 40 N.

In scenarios where there are additional vertical forces or the surface is not horizontal, the normal force is calculated by summing all vertical forces, where forces pushing the block into the surface increase the normal force and forces lifting the block reduce the normal force. However, in this example, such complexities are absent, making the calculation straightforward.

Final answer:

A vector is used to represent the direction and strength of a force. Force is a vector quantity depicted in diagrams with arrows indicating magnitude and direction, with positive and negative vectors designating direction relative to a reference point.

Explanation:

A vector can be used to represent the direction and strength of a force. Force is a vector quantity, which means it has both a magnitude (strength) and a direction. For example, to represent a force of 20 N towards the East, you would draw an arrow 10 cm long towards the right if using a scale of 1 cm = 2 N. The direction of the force can be indicated using compass points or arrows showing the reference direction, and negative vectors represent forces in the opposite direction of the chosen positive reference direction.

The study of forces is known as dynamics, which considers how forces act on objects to cause motion. Vectors are used to visually represent forces in diagrams and can be added together using the head-to-tail method or trigonometric methods to determine the resultant force when multiple forces are acting.

When multiple forces are at work, such as two people pushing on a third person in different directions, the total force acting on the person can be represented by adding the vectors to find the resultant. This addition takes into account both the magnitude and direction of each force.

We must always take note that mass is an inherent property of an object. It never change unless there is change in size of the object. While weight is the product of mass and gravity, so it changes depending on the gravitational pull.

If the gravitational pull decreases as he moves from the poles to the equator, therefore its weight will decrease.

Answer:

D.Its weight will decrease

According to the calculations, the water balloon does not hit the professor. It comes closest to her when it is approximately 0.316 meters away.

In order to determine if the water balloon hits the professor, we need to calculate the time it takes for the balloon to reach the ground. The time can be found using the equation:

t = \sqrt{\frac{2h}{g}}

Where t is the time, h is the height (18.0 meters), and g is the acceleration due to gravity (9.8 m/s^2). Plugging in the values, we find that it takes approximately 1.52 seconds for the balloon to reach the ground.

We also need to calculate the horizontal distance the professor walks in that time. The distance can be found using the equation:

d = vt

Where d is the distance, v is the velocity (0.450 m/s), and t is the time (1.52 seconds). Plugging in the values, we find that the professor walks approximately 0.684 meters during that time.

Therefore, since the professor is 1.00 meter from the point directly beneath the window, the balloon does not hit her. It comes closest to her when it is 0.316 meters away from her.

Actually we could create a triangle in this case. The hypotenuse is the radius of Earth plus the height above the earth, while the two sides are the radius of Earth and the scope of vision.

That is:

(6,400,000 m + 100 m)^2 = (6,400,000 m)^2 + b^2

b^2 = 1,280,010,000

b = 35,777.23 m

You can see 35,777.23 m far.

Answer:

Sulfuric acid.

Explanation:

A battery is a device which contains one or more electrical chemical cells which are connected in a electrical circuit to power the objects like flashlight, speaker, etc.

When a battery is supply electric power then its positive terminal classified as cathode and negative as anode.

And as we know that the electrolyte in a typical wet storage battery or cell contains 67% water and 33% of sulfuric acid.

Answer:

Energy  the electron have initially [tex]E_4=-0.85 \rm ev[/tex],

The change in energy if the electron from part a now drops to the ground state is [tex]12.75\rm ev[/tex]

Explanation:

Given information:

Electron have initially in the n=4 excited state,

We know,

Energy of an electron is given by,

[tex]E_n=-13.6\rm ev\times\frac{z^2}{n^2}[/tex]

On substituting n=4 for excited state energy,

[tex]E=-13.6\rm ev\times\frac{1^2}{4^2}=-0.85\rm ev[/tex]

Change in energy from excited state to ground state,

For ground state n=1,

[tex]E=-13.6\rm ev\times z^2\times( \frac{1}{(n_2)^2}-\frac{1}{(n_1)^2})[/tex]

On substituting [tex]n_1=1[/tex],[tex]n_2=4[/tex],

[tex]\Delta E=E_4-E_1=-13.6\rm ev\times 1^2\times( \frac{1}{(4)^2}-\frac{1}{(1)^2})=12.75ev[/tex]

Hence, energy  the electron have initially [tex]E_4=-0.85 \rm ev[/tex],

NOTE:- [tex]1\rm ev=-1.602\times 10^{-19}joule[/tex]

Energy  the electron have initially [tex]E_4=-0.85 \rm ev[/tex],

The change in energy if the electron from part a now drops to the ground state is [tex]12.75\rm ev[/tex]

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Answer: Option (a) is the correct answer.

Explanation:

When only one element gets displaced upon chemical reaction between a compound and an element then it is known as a single replacement reaction.

For example, [tex]Fe_{2}O_{3}(s) + 2Al(s) \rightarrow Al_{2}O_{3}(s) + 2Fe(l)[/tex]

On the other hand, when two compounds chemically react together and their ions get replaced by each other then it is known as a double replacement reaction.

For example,  [tex]AgNO_{3}(aq) + NaCl(aq) \rightarrow AgCl(s) + NaNO_{3}(aq)[/tex]

Thus, we can conclude that the reaction which has two reactants with ions that seem to switch places clue can be used to identify a chemical reaction as a replacement reaction.

The pitch of a note is determined by its frequency, with higher frequencies leading to higher pitches. The quality, or timbre, of a note depends on the shape of the waveform, influenced by various frequencies and phases of sound waves. These aspects combine to give each note its unique character.

The quality and pitch of a note depend on different aspects of sound waves. The pitch of a note is primarily determined by its fundamental frequency, which is measured in hertz (Hz). A higher frequency results in a higher pitch, making a note sound “sharper” or higher on the musical scale. For example, the piano note middle C has a frequency of 261.63 Hz. Musical intervals, like the octave, are based on the doubling of frequencies.

On the other hand, the quality or timbre of a note depends on the waveform's shape, which is influenced by the frequencies and phases of other sound waves produced alongside the fundamental frequency. This complexity allows us to distinguish between different instruments playing the same note due to the variety in waveforms. The timbre is what makes the same note played on a trumpet distinctly different from the same note played on a clarinet.

In summary, while pitch is a direct correlation to the frequency of sound, quality or timbre involves the intricate interplay of multiple frequencies and their waveform shapes, contributing to the unique character of each musical note.

Answer:

positive charge

The nucleus contains protons, which have a positive charge equal in magnitude to the electron's negative charge. The nucleus may also contain neutrons, which have virtually the same mass but no charge.

Explanation:

The puma, cougar, or mountain lion leaves the ground to make a leap with a speed of approximately 8.32 m/s.

To find the speed at which the animal leaves the ground, we can use the kinematic equation for projectile motion:

[tex]\[v = \sqrt{2gh},\][/tex]

where [tex]\(v\)[/tex] is the speed, [tex]\(g\)[/tex] is the acceleration due to gravity (approximately [tex]\(9.81 \, \text{m/s}^2\))[/tex], and [tex]\(h\)[/tex] is the vertical height.

Given that the height  [tex]\(h\)[/tex] is 13.7 ft, we first convert it to meters:

[tex]\[h = 13.7 \, \text{ft} \times 0.3048 \, \text{m/ft} = 4.1756 \, \text{m}.\][/tex]

Substituting [tex]\(h\)[/tex] into the equation, we have:

[tex]\[v = \sqrt{2 \times 9.81 \, \text{m/s}^2 \times 4.1756 \, \text{m}} \approx 8.32 \, \text{m/s}.\][/tex]

Final answer:

The magnitude of the average acceleration the football player experiences is 38.02 m/s², and the direction of the acceleration is backward, towards the line of scrimmage.

Explanation:

To calculate the magnitude and direction of the average acceleration experienced by the football player, we use the following kinematic equation:

a = (v_f - v_i) / t

Where:

Given:

Now we can plug these values into our equation to find a:

a = (0 - 7.68 m/s) / 0.202 s

a = -7.68 m/s / 0.202 s

a = -38.02 m/s2

The negative sign indicates that the acceleration is in the opposite direction of the player's initial motion. Since the player was moving forward and came to a stop, the acceleration is directed backward, towards the line of scrimmage.

Answer:

[tex]108\ N[/tex]

Explanation:

Mass of object, [tex]m=1.50\ kg.[/tex]

Length of string, [tex]r=0.50\ m.[/tex]

Tangential speed, [tex]v_t=6.0\ m/s.[/tex]

Now, centripetal force F of a object moving in given radius r and mass m moving with velocity v.

Here , object moves along the ends of string. Therefore, radius is equal to length of string.

[tex]F=\dfrac{m \times v_t^2}{r}.[/tex]

Putting values of m,v and r in above equation.

We get, [tex]F=\dfrac{1.50\times (6.0)^2}{0.50} \ N=108 \ N.[/tex]

Hence, this is the required solution.

By six times, a person should jump farther on the moon as compared to the earth if the takeoff speed and angle are the same.

The height of the earth can be computed using the third equation of motion. The third equation of motion, referred to as one of the kinematic equations, relates the final velocity, initial velocity, acceleration, and displacement of an object.

The height of the earth is given as:

[tex]v^2-u^2= 2gH_e\\v^2 = 2\times9.8\timesH_e\\H_e = v^2/2g[/tex]

The height of the moon is given as:

[tex]v^2-u^2 = 2(g/6)H_m\\v^2 = g/3H_m\\H_m = 3v^2/g[/tex]

The ratio of both heights is given as:

[tex]H_m/H_e = 3v^2/g/(v^2/2g)\\H_m/H_e = 6\\H_m = 6H_e[/tex]

Hence, by six times, a person should jump farther on the moon as compared to the Earth if the takeoff speed and angle are the same.

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A person can jump about six times further on the Moon compared to Earth given the same initial angle and speed. This is because the acceleration due to gravity on the moon is one-sixth that of Earth, resulting in a weaker gravitational pull.

The topic in question involves the concept of gravitational forces and its influence on the jump length of a person on Earth versus the Moon. The acceleration due to gravity on the Moon is about one-sixth that of Earth, meaning the gravitational force is much weaker. Therefore, if a person jumps with the same speed and angle on the moon as on Earth, they would be able to jump approximately six times farther due to the weaker gravitational pull.

For better understanding, consider this example. If a person jumps and covers a certain distance on Earth in a given time, the same person would be airborne six times as long on the Moon if they jumped with the same velocity. This is due to the inverse relationship between the time of flight (airborne time) and acceleration due to gravity (g). Since g for the Moon is one-sixth that of Earth, a person can jump about six times further.

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Answer:

1.715 Joules

Explanation:

ΔPE = m * g * Δh = 0.7 kg * 9.8 N/kg * 0.25 m = 1.715 N*m = 1.715 J

Answer:

10 calories

Explanation:

The thermal energy needed to increase the temperature of a substance is given by

[tex]Q=m C \Delta T[/tex]

where

m is the mass of the substance

C is the specific heat of the substance

[tex]\Delta T[/tex] is the increase in temperature

In this problem, the mass of the ice is m=20 g, the specific heat is C=0.5 calories/gram°C, and the increase in temperature is [tex]\Delta T=1^{\circ}[/tex]. Therefore, the energy required is

[tex]Q=(20 g)(0.5 cal/g^{\circ}C)(1^{\circ}C)=10 cal[/tex]

Answer:

Newton's third law of motion

Explanation:

As per Newton's third law of motion, every action has its equal and opposite reaction.

When a jet aircraft takes off it exerts a force and gains upward acceleration, the same force is applied on your body as it is moving along the jet hence this force tries to push you back into the seat.

For instance, while rowing a boat you try to apply force on water with paddles in backward direction, the same amount of force is reverted by water thus moving the boat in forward direction.

Hence Newton's third law of motion explains the phenomena.

Answer:

Newton's third law of motion

Explanation:

As per Newton's third law of motion, When two bodies interact they apply force to one another that are equal in magnitude and opposite  in direction.

During the take off a jet aircraft it exerts a force and gain upward acceleration, the same amount of force is applied on our body because we are in contact with jet due to third law we pushed back into the seat..

[tex]F_1=-F_2[/tex]

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First calculate the acceleration using the formula:

d = v0 t + 0.5 a t^2

where d is distance = 200 m, v0 = initial velocity = 0, t is time = 9s, a = acceleration (?)

200 = 0 + 0.5 * a * 9^2

a = 4.94 m/s^2

Force is mass times acceleration, therefore:

F = m a = 1200 kg * 4.94 m/s^2

F = 5,925.93 N

To calculate the force exerted on the car by the road, we first find the acceleration of the car using the formula: a = Δv/Δt. After calculating the acceleration to be approximately 9.88 m/s², we then use Newton's second law, F = ma, which results in the force being approximately 11856 N.

In physics, to find the force exerted, we need to apply Newton's second law of motion which states that the force acting on an object is equal to the mass of that object multiplied by its acceleration (F = ma). Given the mass of the car (1200 kg) and the need to find acceleration, we can use the formula for acceleration: a = Δv/Δt, where Δv is the change in velocity and Δt is the change in time. Initially, the car is at rest so initial velocity is zero and the final velocity can be calculated as v = a*t. Now substituting the values into the equation, 200m = 0.5*a*(9s)^2, we find acceleration a=9.88 m/s². Then, applying Newton's second law F = 1200kg * 9.88m/s² we get the force exerted on the car by the road is approximately 11856 N.

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Answer:

a)Mechanical to heat energy.

b)potential to kinetic energy

c)kinetic to potential energy

d)kinetic to heat energy.