five coulombs (5 c) of charge pass through the element from point a to point b. if the energy absorbed by the element is 120 j, determine the voltage across the element.

The top of the 12 ft ladder that leans against the house, and the bottom of the ladder is 9 ft from the side of the house = 7.9 ft

The triangle formed by the ladder must be a right angle with a hypotenuse (Side opposite to right angle) of 12 feet since the side of the house must be vertical to the ground to form a right angle.

Let x represent how high the ladder's top is above the ground.

We have the following using the Pythagoras theorem of right triangles:

c² = a² + b²

12² = 9² + x²

x² = 144 - 81

= 63

Hence,

x = √63

= 7.9 ft

The question is incomplete, it should be:

A 12 - ft ladder leans against the side of a house. the bottom of the ladder is 9 ft from the side of the house. how high is the top of the ladder from the ground? if necessary, round your answer to the nearest tenth.

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The maximum height reached is approximately 101 meters above the ground.

Using this equation, we can solve for the time in the air, which turns out to be approximately 4.06 seconds. To find the range of the objects, we can use the horizontal component of the velocity of the cannonball, which is given by :

[tex]v = v 0 cos(theta),[/tex]

where v0 is the initial velocity of the cannonball and theta is the angle of elevation. We can use the equation of motion for the vertical component of the motion, which is given by:

[tex]height = v0y * t + (1/2) * g * t^2,[/tex]

where v0y is the initial vertical velocity and g is the acceleration due to gravity.

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Adam lifts a book from the floor, carries it across the room, and places it on a high shelf, he does work only while he carries the book across the room, which is in option B, as work = force x distance.

According to the equation for work (W = FD), work is only done when a force is applied to an object and it moves some distance as a result of that force, when Adam lifts the book from the floor, he applies force to it, but the book does not move any distance, so no work is done when the object doesn't move, but when he moved the book, work was done.

Hence, he does work only while he carries the book across the room, which is in option B, as he lifts a book from the floor and carries it across the room.

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E: "Removing charge from the rod" will increase the electric field strength at the position of the dot.

The electric field strength at the position of the dot depends on the charge and the distance from the charge. Therefore, any change that affects the charge or the distance will also affect the electric field strength.

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(a) The marginal cost function is MC = 3Q + 464.

(b) The marginal cost function is MC = 160 + 5 + 6Q + 6Q^2.

The marginal cost (MC) of a product is the change in the total cost of producing an additional unit of the product.

(a) AC = 1.5Q + 4 + 460

The total cost (TC) of producing Q units is given by:

TC = AC * Q

TC = (1.5Q + 4 + 460) * Q

TC = 1.5Q^2 + 4Q + 460Q

TC = 1.5Q^2 + 464Q + 460

The marginal cost function is given by the derivative of the total cost function with respect to Q:

MC = dTC/dQ

MC = d/dQ (1.5Q^2 + 464Q + 460)

MC = 3Q + 464

b) AC = 160 + 5 + 3Q + 2Q²

The total cost of producing Q units is given by:

TC = AC * Q

TC = (160 + 5 + 3Q + 2Q^2) * Q

TC = 160Q + 5Q + 3Q^2 + 2Q^3

The marginal cost function is given by the derivative of the total cost function with respect to Q:

MC = dTC/dQ

MC = d/dQ (160Q + 5Q + 3Q^2 + 2Q^3)

MC = 160 + 5 + 6Q + 6Q^2.

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When the angle is 90 degrees up, the only force acting in a downward direction is gravitational force, with magnitude mg, where m is mass and g is gravitational acceleration.

m = 2.25 kg, g = 9.8 /s²

F = mg = 2.25 × 9.8

F = 22.05 N.

An item falling freely in a vacuum is said to accelerate gravitationally in physics. This is the constant acceleration brought on just by the gravitational pull.

By putting an object in a vacuum chamber and monitoring the object's speed as a function of time as it accelerates, one can calculate the gravitational acceleration. This is the approach that Galileo popularized.

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It is demonstrated that for each k, there exists a set of k positive integers whose difference has an even number of prime components, counted with multiplicity.

Let's construct the set of positive integers using the following algorithm:

Start with the first k prime numbers: 2, 3, 5, 7, 11, ..., p_k.

Define the i-th integer in the set as the product of the first i prime numbers: a_i = 235*...*p_i.

Claim: For any two integers in the set, their difference has an even number of prime factors, counted with multiplicity.

Proof:

Let a_i and a_j be two integers in the set such that i < j. We want to show that the difference a_j - a_i has an even number of prime factors, counted with multiplicity.

Notice that a_j - a_i can be written as:

a_j - a_i = 235*...p_i(235*...*p_j/2 - 1)

The first term on the right-hand side has i prime factors, and the second term has an odd number of prime factors. To see why the second term has an odd number of prime factors, notice that all the prime factors of 235*...p_j are also prime factors of 235...*p_i, so they cancel out in the difference.

a_j - a_i has i prime factors plus an odd number of prime factors, which is an even number of prime factors. This completes the proof.

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Answer:

(a) The kinetic energy of the particle will decrease if the particle's velocity changes from -3 m/s to -2 m/s.

(b) The kinetic energy of the particle will increase if the particle's velocity changes from -2 m/s to 2 m/s.

(c) The work done on the particle in both situations is positive. This is because work is the energy transferred to or from a system and the kinetic energy of the particle increases in both cases, indicating energy was transferred to the particle.

Answer:

A person walking, a soaring baseball, a crumb falling from a table and a charged particle in an electric field are all examples of kinetic energy at work.

Explanation:

Walking and running. Cycling. In a windmill, when the moving air hits the blades, it causes rotation which ultimately leads to the generation of electricity. In a hydropower plant, when the kinetic energy of the moving water hits the turbine the kinetic energy of the water gets converted to mechanical energy.

A spacecraft can reduce its speed during a trip to Mars by firing reverse rockets to increase force acting opposite of the direction of travel.

option C.

To reduce the speed of a spacecraft during a trip to Mars, the most common method is to fire reverse rockets, also known as braking thrusters.

These thrusters are used to generate a force that acts in the opposite direction of the spacecraft's motion, slowing it down. This is called a deceleration burn, and it is an important step in the process of entering into orbit around a planet or landing on its surface.

The reverse thrust slows down the spacecraft, reducing its speed and allowing it to be captured by the planet's gravity. This is crucial for the success of the mission and ensures that the spacecraft can be safely guided into orbit or landed on the surface of the planet.

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If a graded receptor potential made the resting membrane potential of the axon more negative (for example, -70 mV changes to 75 m), it would be more difficult for this axon to reach the threshold voltage (option D)

The resting membrane potential will become less negative as the extracellular K+ concentration rises.

Because the negative charge inside the cell exceeds the positive charge outside, the resting membrane potential is negative.

The distinction between the inside and outside of the cell is lessened as a result.

The resting membrane potential would be impacted by a change in Na+ or K+ conductance.

Since the membrane is more permeable to K+, a change in K+ conductance would have a bigger impact on resting membrane potential than a change in Na+ conductance.

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Average acceleration is a) 2.22 [tex]m/s^2[/tex] b) hot rod travels 78.4 m c) time is 20 seconds

(a) To find the average acceleration, we need to use the formula: average acceleration = change in velocity / time.

First, we convert 60 km/h to m/s:

60 km/h x 1000 m/km x 1 h/3600 s = 16.67 m/s

So the change in velocity is:

16.67 m/s - 0 m/s = 16.67 m/s

And the time is:

7.5 s

Therefore, the average acceleration is:

average acceleration = (16.67 m/s) / (7.5 s) = 2.22 m/s^2

(b) To find the distance traveled, we can use the formula: distance = initial velocity x time + 0.5 x acceleration x time^2.

The initial velocity is 0 m/s, so the formula becomes:

distance = 0.5 x acceleration x time^2

Plugging in the values, we get:

distance = 0.5 x 2.22 m/s^2 x (7.5 s)^2 = 78.4 m

Therefore, the hot rod will travel 78.4 meters during the 7.5 seconds.

(c) We can use the formula: distance = 0.5 x acceleration x time^2, and solve for time.

Plugging in the values, we get:

0.40 km x 1000 m/km = 400 m

acceleration = 2.22 m/s^2

So the formula becomes:

400 m = 0.5 x 2.22 m/s^2 x time^2

Solving for time, we get:

time = sqrt(400 m / (0.5 x 2.22 m/s^2)) = 20 s

Therefore, it would take 20 seconds for the hot rod to travel 0.40 km with constant acceleration of 2.22 m/s^2.

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The speed of the GPS satellite can be calculated using the following formula:

v = √(GM/r)

r = RE + h = 6.37 x 10^6 m + 20,200,000 m = 2.06 x 10^7 m

v = √(GM/r) = √((6.67 x 10^-11 Nm^2/kg^2)(5.97 x 10^24 kg)/(2.06 x 10^7 m)) ≈ 3,870 m/s

Therefore, the speed of the GPS satellite is approximately 3,870 m/s.

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(a) The final speed of the cooler is 5.77 m/s.

(b) In the presence of friction, the final speed of the cooler is 3.43 m/s.

The final speed of the cooler is calculated by applying work energy theorem as shown below;

Change in kinetic energy of the cooler = work done on the cooler

¹/₂mv² = fd

v² = (2fd) / m

v = √(2fd) / m

where;

The final speed of the cooler is calculated as;

v = √(2 x 30 x 2) / 3.6

v = 5.77 m/s

At the given coefficient of friction, the final speed is calculated as;

v = √(2Ffd) / m

where;

Ff = μW

where;

v = √(2μWd) / m

v = √(2 x 0.3 x 3.6 x 9.8 x 2) / 3.6

v = 3.43 m/s

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Jake's velocity at the lowest point of the swing is 7 m/s.

Potential energy is the energy stored in any object or system due to the position or arrangement of its parts. It is, however, unaffected by factors outside of the object or system, such as air or height. Kinetic energy, on the other hand, is the energy of moving particles in an object or system.

To solve this problem, we need to use the conservation of energy principle, which states that the total energy in a system remains constant.

At the highest point, Jake has potential energy (due to his position above the ground), but no kinetic energy (since he is not moving).

As he swings down, his potential energy is converted to kinetic energy, and at the lowest point of the swing, he has the maximum kinetic energy and minimum potential energy. Then, as he swings back up, the process is reversed.

To calculate Jake's potential energy at the top of the swing, we use the formula:

PE = mgh

where m is the mass of Jake, g is the acceleration due to gravity (9.8 m/s²), and h is the height above the ground. Substituting in the values, we get:

PE = (20 kg)(9.8 m/s²)(2 m) = 392 J

This is Jake's potential energy at the top of the swing. At this point, he has no kinetic energy.

At the lowest point of the swing, Jake has converted all of his potential energy into kinetic energy. We can use the conservation of energy principle to find his kinetic energy at this point:

KE = PE

where KE is kinetic energy and PE is potential energy. Substituting in the values, we get:

KE = 392 J

This is Jake's kinetic energy at the lowest point of the swing.

To find Jake's velocity at the lowest point, we can use the formula for kinetic energy:

KE = (1/2)mv²

where v is velocity. Rearranging the formula to solve for v, we get:

v = √((2KE)/m)

Substituting in the values, we get:

v = √((2(392 J))/(20 kg)) = 7.0 m/s

This is Jake's velocity at the lowest point of the swing.

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b in terms of a that satisfies the given condition is, [tex]b = \ln(3e^a - 2)[/tex].

The equation of the curve is y = e^x.

The shaded region A is the area under the curve between x = 0 and x = a, so its area is given by,

[tex]A = \int_0^a e^x dx = e^a - 1[/tex]

The area labeled B is four times the area labeled A, so its area is given by,

B = 4A = 4(e^a - 1)

To express b in terms of a, find the value of b that satisfies,

[tex]\int_0^a e^x dx = 3(e^a - 1)[/tex]

Using the formula for the integral of e^x, we get:

[tex]e^b - e^a = 3(e^a - 1)[/tex]

Solving for b, we get:

[tex]b = \ln(3e^a - 2)[/tex]

So the area labeled B is [tex]4(e^a - 1)[/tex], and the value of b that satisfies the given condition is [tex]b = \ln(3e^a - 2)[/tex].

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When a weak stimulus is applied in rapid succession, it will often reach threshold due to Temporal summation.

Stimulus is the effect that cause a change in the external or internal environment which brings physiological responses.

Here,

The weak stimulus applied is converted into a large signal so that it could reach the threshold.

Temporal summation is the phenomenon that could convert a series of weak stimuli at a specific frequency into a large signal and to achieve action potential.

Hence,

When a weak stimulus is applied in rapid succession, it will often reach threshold due to Temporal summation.

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If the mass of an object is tripled while the force acting upon it is kept constant, the acceleration of the object will be reduced to one-third of its original value.

This can be explained using Newton's second law of motion, which states that the acceleration of an object is directly proportional to the force applied to it and inversely proportional to its mass.

In this scenario, the force is held constant, but the mass is increased by a factor of three. As a result, the acceleration will decrease by a factor of three, since the same force is now acting on a much heavier object. Therefore, the object will experience a lower acceleration than before, making it harder to move or change its speed or direction.

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Step-by-step Explanation

Given: Diameter (D) of the capillary tube =  m

Surface Tension (T) =

The angle of contact () =

Acceleration due to gravity (g) =

The temperature of water =

To Find: The height (h) of rising of water in the capillary tube

Solution:

Formula to find the height of the rise

The following expression is used to find the height (h) of rising of water in the capillary tube;

Where,  is the density of water, and  is the radius of the capillary tube.

Calculating the height of the rise in the capillary tube

Since the diameter of the capillary tube is , the radius of the tube will be;

And, at , the density of water is

Substituting all the required values in the above formula, we get;

Hence, the water will rise in a capillary tube to a height of

If a machine does some kind of work faster, then this mean that the power rating of the machine is higher. Power rating is directly proportional to the work done.

The power rating of an equipment is the highest power input which is allowed to flow through a particular equipment. According to the particular discipline, the power may be referred to as the electrical or mechanical power.

Work is proportional to the energy, and higher power means higher energy present in an object. If a machine does work at a faster rate, this means that it has high power rating.

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Answer:

A

Explanation:

A student wants to launch a toy dart As time t = 0, release a ball that has been resting near the Earth's surface. Allow a cart to leave rest and move down a 40°40° inclination with regard to the ground.

The graphs which could represent the vertical component of the velocity as a function of time for the dart and the target immediately after the dart is launched and the target begins to fall is Dart: above x-axis, decreasing; Target: below x-axis, decreasing.

Velocity is the directional speed of a moving object as an indicator of the rate at which its position changes as perceived from a given frame of reference and measured by a particular standard of time. The idea of ​​speed is important in kinematics, the part of classical mechanics that explains the motion of things.

Velocity is a physical vector quantity that requires both magnitude and direction to be determined. Velocity is a scalar absolute value of speed, a consistently derived unit whose quantity is measured in SI (metric system) in meters per second.

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The above question is incomplete, the complete question is-

A student wants to launch a toy dart toward a target that hangs from a light string. At time t=0, the dart is launched with an initial speed v0 at an angle θ0 above the horizontal ground. At the instant the dart is launched, the string is cut such that the target begins to fall straight down. The positive horizontal direction is considered to be to the right, and the positive vertical direction is considered to be up.

Which of the following graphs could represent the vertical component of the velocity as a function of time for the dart and the target immediately after the dart is launched and the target begins to fall?

Answer:

Explanation:

The problem you're describing involves two blocks connected by a rope over a pulley, with each block resting on a separate incline plane. The acceleration of each block and the tension in the rope can be determined using the principles of dynamics and conservation of energy.

Let's call the masses of the two blocks m1 and m2, the incline angles of the two planes θ1 and θ2, and the acceleration of each block a1 and a2.

The net force on each block is given by the sum of the gravitational force, the normal force, and the tension in the rope.

For block 1:

m1 * g * sin(θ1) - m1 * a1 = T

For block 2:

m2 * g * sin(θ2) - m2 * a2 = -T

where g is the acceleration due to gravity and T is the tension in the rope.

From these equations, we can see that the tension in the rope is equal in magnitude but opposite in direction for each block. The acceleration of each block can be found by rearranging the equations and solving for a1 and a2.

The condition for block 2 to be moving down its incline plane is that the net force on the block must be in the direction of motion, which means that the tension in the rope must be less than the gravitational force acting on the block. This can be expressed as:

T < m2 * g * sin(θ2)

Here is a definition of each variable in the problem:

m1: mass of block 1

m2: mass of block 2

θ1: incline angle of the first plane

θ2: incline angle of the second plane

a1: acceleration of block 1

a2: acceleration of block 2

g: acceleration due to gravity

T: tension in the rope

I hope this helps! Let me know if you have any other questions or if you need further clarification.

The energy of each photon in electron volts is, 2.07.

Stopping potential is the minimum negative voltage applied to the anode to stop the photocurrent. The maximum kinetic energy of the electrons equal the stopping voltage, when measured in electron volt.

Stopping potential = Energy of light wave falling - energy of each photon

Energy of light wave falling = [tex]\dfrac{hc}{\lambda}[/tex]

Energy of light wave falling = [tex]\dfrac{hc}{\lambda}[/tex]

Energy in electron volts for a wave of wavelength 520 nm is, 2.37 eV.

Now,

Stopping potential = Energy of light wave falling - energy of each photon

0.3V = 2.37 - energy of each photon

Energy of each photon = 2.07

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Answer:

Explanation:

Here is the definition of each variable used in the expression for the electric field strength:

• r: radial distance from the center of the shell to the point where the electric field strength is being calculated

• a: radius of the shell

• b: thickness of the shell

• ρ_0: charge density in the shell

• ε_0: permittivity of free space, a constant that relates the electric flux density to the electric field strength. Its value is approximately 8.854 x 10^(-12) C^2/Nm^2.

• E: electric field strength, a vector quantity that describes the force experienced by a unit positive test charge placed at a particular point in an electric field.

• ∇: the gradient operator, a vector differential operator that describes the rate of change of a scalar field with respect to position.

• ∫: the definite integral symbol, denoting the sum of an infinite number of infinitesimal quantities over a specified range.

• dr': infinitesimal element of the radial distance used in the integration over the shell.

The electric field strength in a region is given by the gradient of the electric potential, V, in that region. The electric potential is related to the charge distribution, ρ, by the Poisson equation:

∇^2V = -(1/ε_0) * ρ

where ε_0 is the permittivity of free space.

If we assume the charge distribution is spherically symmetric, such that ρ = ρ(r), we can express the electric potential as:

V(r) = (1/4πε_0) * ∫(ρ(r')/|r-r'|) dV'

We can simplify this expression by assuming that the charge distribution is confined to a thin shell of radius a and thickness 2b, so that ρ(r) = ρ_0 for a-b <= r <= a+b and ρ(r) = 0 elsewhere. The electric potential in the region a can then be calculated by integrating over the shell:

V(r) = (1/4πε_0) * ρ_0 * ∫_{a-b}^{a+b} (1/|r-r'|) * dr'

To find the electric field strength, we need to take the gradient of the electric potential:

E = -∇V

Substituting in the expression for the electric potential, we get:

E = -∇[(1/4πε_0) * ρ_0 * ∫_{a-b}^{a+b} (1/|r-r'|) * dr']

So, the electric field strength in the region a is proportional to the gradient of the integral of the charge distribution over the shell, and is expressed in terms of the radius, a, the thickness, b, the charge density, ρ_0, and the permittivity of free space, ε_0.

a) Travelled 20.57 meters before coming to a stop.

b) When travelled half the distance, the speed is 2.6 m/s, which is less than 6 m/s.

Speed is a measure of how fast an object is moving, without regard to the direction of its motion. It is defined as the distance travelled by an object per unit of time. Speed is a scalar quantity, which means it only has magnitude (i.e., numerical value) and not direction. The standard unit of speed is meters per second (m/s) in the International System of Units (SI), although other units such as kilometres per hour (km/h) and miles per hour (mph) are also commonly used. It can be calculated as the ratio of distance traveled by an object to the time taken to cover that distance.

For example, if a car travels 100 meters in 10 seconds, its speed can be calculated as 100 meters divided by 10 seconds, which equals 10 meters per second. Speed can also be constant, if the object is moving at a constant rate without changing its speed, or variable, if the object's speed changes over time.

(a) To determine how far travelled before stopping, use the kinematic equation:

[tex]v^2 = u^2 + 2as[/tex]

where,

v = final velocity (0 m/s, since you come to a stop)

u = initial velocity (12 m/s)

a = acceleration (-3.5 m/s^2, since decelerating)

s = distance traveled (unknown)

Rearranging the equation to solve for s, we get:

[tex]s = (v^2 - u^2) / (2a)[/tex]

Substituting in the known values, we get:

[tex]s = (0 - (12 m/s)^2) / (2*(-3.5 m/s^2)) = 20.57 m[/tex]

Therefore, travelled 20.57 meters before coming to a stop.

(b) To determine speed, travelled half the distance, use the kinematic equation:

[tex]s = ut + 0.5at^2[/tex]

where,

t = time elapsed (unknown, but  use the fact that have travelled half the distance)

s = distance traveled (half of 20.57 m = 10.285 m)

u = initial velocity (12 m/s)

a = acceleration (-3.5 m/s^2)

Substituting the known values,

[tex]10.285 m = (12 m/s)t + 0.5(-3.5 m/s^2)t^2[/tex]

Simplifying and rearranging, a quadratic equation is obtained:

[tex]1.75t^2 - 12t + 10.285 = 0[/tex]

Solving  t using the quadratic formula,

t = 2.52 s (rounded to two decimal places)

Now, to find your speed at this point, we can use the kinematic equation:

[tex]v = u + at[/tex]

Substituting the known values,

[tex]v = 12 m/s + (-3.5 m/s^2)(2.52 s) = 2.6 m/s[/tex]

Therefore, when travelled half the distance, the speed is 2.6 m/s, which is less than 6 m/s.

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The variables in the kinematic equations for motion in one dimension with constant acceleration are time, initial position, initial velocity, initial acceleration, velocity, and position.

The following are accurate definitions for the variables in the kinematic equations for motion in one dimension with constant acceleration:

A. x(t) represents the particle's position at time t as determined by its initial position x. (0).

B. v(t) represents the particle's speed at time t as determined by its initial speed v. (0).

C. The particle's starting position, or the position at time t=0, is represented by the number x(0).

D. The initial velocity of the particle, or its speed at time t=0, is known as v(0).

E. an is the particle's constant acceleration.

It's vital to remember that the x and v subscripts denote the time at which the location or velocity is being measured. As an illustration, x(0) is the particle's position at time.

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The track in relatively brief speed skating has straight stretches and semicircles with a 16-minute diameter. This 68 kg skate makes the maneuver at a steady 12 m/s while exerting 1224 N.

The pace at which a distance changes over time is referred to as speed. It has a dimension of time-distance. As a consequence, the fundamental unit of time as well as the basic measure of distances are combined to form the Special name of speed. Thus, the meter per second (m/s) is the Unit of measure of speed.

r = 8 m.

tangential velocity = 12 m/s.

angular speed is,

ω = v/r

= (12 m/s)/(8 m)

= 1.5 rad/s

centripetal acceleration,

a = r*ω²

= (8 m)*(1.5 rad/s)²

= 18 m/s².

force,

F = m*a

= (68 kg)*(18 m/s²)

= 1224 N

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