A generator (illustrated in the figure) is employed to be a back up in case of loss of power from the electric company. the loop is square (10 cm x 10 cm) and consists of n turns. the magnetic field is constant through the generating volume with magnitude b 0.2 t. the generator runs at a frequency f = 60 hz. how many turns n are required so that the output voltage has a peak value of vpk = 100?

The car travels 368 m before stopping. The answer is B.

Use the work-energy principle, which states that the work done on an object is equal to its change in kinetic energy. We are given the mass (2,500 kg), initial velocity (50.0 m/s), and braking force (8,500 N).

vf^2 = vi^2 + 2ad

where vf is the final velocity (which is zero in this case, since the car stops), vi is the initial velocity (50.0 m/s), a is the acceleration (which is equal to the braking force divided by the mass of the car, or 8 500 N / 2 500 kg = 3.4 m/s^2), and d is the distance traveled before stopping (what we're trying to find).

Plugging in the values, we get:

0 = (50.0 m/s)^2 + 2(3.4 m/s^2)d

Simplifying, we get:

d = (0 - 2 500 m^2/s^2) / (2(3.4 m/s^2)) = 368 m


Therefore, The car travels 368 m before stopping. The answer is B.

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The magnification of the mirror after calculations is 0.99.

We can use the mirror formula and magnification formula to solve this problem:

1/f =[tex]1/d_o + 1/d_i[/tex]

magnification = -[tex]d_i/d_o[/tex]

where f is the focal length of the mirror, [tex]d_o[/tex] is the distance of the object from the mirror, and [tex]d_i[/tex] is the distance of the image from the mirror.

(a) To find the position of the object, we can rearrange the mirror formula:

[tex]1/d_o = 1/f - 1/d_i[/tex]

Substituting the given values, we get:

[tex]1/d_o[/tex] = 1/(-41.5 cm/2) - 1/20.5 cm

Simplifying, we get:

[tex]1/d_o[/tex] = -0.0482 cm^-1

Therefore:

[tex]d_o[/tex] = -20.7 cm

Note that the negative sign indicates that the object is located in front of the mirror.

Therefore, the object is located 20.7 cm in front of the mirror.

(b) To find the magnification, we can use the magnification formula:

magnification = -[tex]d_i/d_o[/tex]

Substituting the calculated values, we get:

magnification = -20.5 cm / (-20.7 cm)

Simplifying, we get:

magnification = 0.99

Therefore, the magnification of the mirror is 0.99.

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The forces (F1, F2, F3, and F4) represent different magnitudes and directions of forces acting on a particular object or system. The relationships provided (A, B, C, D, and E) are comparisons of the magnitudes of these forces.

But without additional context about the forces or their magnitudes, I am unable to provide a valid answer to your question. Please provide more information or clarification. To help you with your question, it would be necessary to have more context about the forces involved (F1, F2, F3, F4) and the situation they are in. However, I can provide a general explanation of the terms you mentioned.

The forces (F1, F2, F3, and F4) represent different magnitudes and directions of forces acting on a particular object system. The relationships provided (A, B, C, D, and E) are comparisons of the magnitudes of these forces.

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Network modifiers affect the structure of a ceramic glass is that they can alter the glass's properties such as its melting point, density, and viscosity. Network modifiers are elements that are added to a glass to break up the network of bonds that hold it together.

In a ceramic glass, the atoms are held together by strong covalent bonds that form a network structure. This network structure gives the glass its strength and hardness. However, the network structure can also make the glass brittle and difficult to process. By adding network modifiers, the bonds between atoms are weakened, and the glass becomes more malleable and easier to process.
The addition of network modifiers to a ceramic glass can significantly alter its properties, making it easier to process and improving its overall performance. The specific effects of network modifiers will depend on the type and amount of modifier added to the glass.

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The speed of the composite body (A + B) after the collision is (b) 6.0 m/s.

To solve this problem, we'll use the principle of conservation of momentum. Since object A is initially at rest, its momentum is 0. Object B has a momentum of mB * 12 m/s. After the collision, the two objects are stuck together, and their combined momentum is (mA + mB) * v. The initial and final momenta must be equal:

mA * 0 + mB * 12 = (mA + mB) * v

Since mA = mB, we can replace mA with mB:

mB * 12 = (mB + mB) * v
12 = 2 * v

Solve for v:

v = 12 / 2
v = 6 m/s

So, the speed of the composite body (A + B) after the collision is 6.0 m/s.

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The absorption of a photon by an electron in a one-dimensional, infinite potential well can cause the electron to transition to a higher energy state.

In a one-dimensional, infinite potential well, the electron is confined to a specific region of space and can only occupy discrete energy levels. When a photon is absorbed by the electron, the electron gains energy equal to the energy of the photon.

If the energy of the photon is equal to the energy difference between the electron's initial energy level and a higher energy level, the electron can transition to the higher energy level.

This transition results in the absorption of the photon and an increase in the electron's energy. The probability of this transition occurring is determined by the selection rules for the system, which depend on the properties of the photon and the system's geometry.

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The enemy is 1,122.6 meters away when you open fire.

We can use the Rayleigh criterion, which states that two point sources are just resolvable if the center of the Airy disk of one is directly over the first minimum of the Airy disk of the other.

The angular resolution is given by:

θ = 1.22 λ/D

where λ is the wavelength of the light, and D is the diameter of the pupil.

θ = 1.22 x (555 x 10^-9 m) / 4.9 x 10^-3 m = 1.38 x 10^-5 radians

Now, we can use trigonometry to determine the distance at which an object of 3.1 cm would subtend an angle of 1.38 x 10^-5 radians:

tan θ = opposite/adjacent

tan (1.38 x 10^-5) = 0.0155 m / distance

distance = 0.0155 m / tan (1.38 x 10^-5) = 1,122.6 meters

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Dual convex lenses follow a set of rules that govern their behavior when light passes through them. These rules include:

1. The incoming light rays are refracted (bent) at the first lens surface, causing them to converge towards the optical axis.

2. The converging light rays then pass through the second lens surface and are refracted again, causing them to diverge away from the optical axis.

3. The point where the refracted light rays converge or diverge is known as the focal point.

4. The distance between the lens and the focal point is known as the focal length.

5. The magnification of the image formed by the lens is determined by the ratio of the distance between the object and the lens (object distance) to the distance between the image and the lens (image distance).

Overall, dual convex lenses are powerful tools for bending and focusing light, and they play a crucial role in many fields, from medicine to astronomy.

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The speed of the boxcar after 9.0 seconds is approximately 3.1 m/s. Therefore, the correct answer is D. 3.1 m/s.

The force acting on the boxcar down the grade is given by the component of the weight of the boxcar along the grade, which is equal to (125 tons)(2000 kg/ton)(9.8 m/s^2)(sin(2.0°)) = 4260 N. Since there is no friction, this force is the only force acting on the boxcar and it will accelerate down the grade.

We need to find the speed of a 125-ton boxcar after 9.0 seconds on a frictionless 2.0° grade.

First, let's convert the mass of the boxcar to kilograms: 1 ton = 1000 kg, so 125 tons = 125,000 kg.

Next, we need to find the acceleration of the boxcar down the slope. The gravitational force acting on the boxcar is F = m * g, where m is the mass and g is the acceleration due to gravity (approximately 9.81 m/s²).

However, since the slope is at an angle, we need to consider only the component of the gravitational force acting along the slope.

To do this, we multiply the gravitational force by the sine of the angle (2.0°):
a = g * sin(2.0°)

Now, we can find the acceleration:
a ≈ 9.81 m/s² * sin(2.0°) ≈ 0.342 m/s²

Next, we'll use the equation v = a * t, where v is the final velocity, a is the acceleration, and t is the time (9.0 seconds) to find the boxcar's speed:
v = 0.342 m/s² * 9.0 s ≈ 3.078 m/s

Rounded to one decimal place, the speed of the boxcar after 9.0 seconds is approximately 3.1 m/s. Therefore, the correct answer is D. 3.1 m/s.

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The height the ball will reach if the initial kinetic energy is double is 4 times the original height (4h).

The initial kinetic energy of the ball is given as K0, and it is related to the initial velocity v₀ by the formula [tex]K_0 = 1/2mv0^2[/tex], where m is the mass of the ball. When the ball is shot straight up, it reaches a maximum height h, which can be calculated using the formula[tex]h = v_0 {^2/2g[/tex], where g is the acceleration due to gravity.

If the initial kinetic energy of the ball is doubled, then the initial velocity of the ball will also double, since [tex]K_0 = 1/2mv0^2[/tex].

Therefore, the new initial velocity is
[tex]v_0 = \sqrt{(2K_0/m)[/tex]
[tex]= \sqrt(21/2m*v_0 ^ {2}/m)[/tex]
[tex]= \sqrt{(2)*v_0.[/tex]

Using the formula for maximum height, the new maximum height h' can be calculated as [tex]h' = v_0^2/2g = (\sqrt{(2)*v_0)^2}/2g = 2v_0^2/2g = 2h.[/tex]

Therefore, the new height the ball will reach if the initial kinetic energy is double is 2 times the original height (2h), or 4 times the original height (4h) if compared to the initial height before being shot up.

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Ultimately, it is the combination of these factors that determines the maximum safe speed at which a car can travel around a flat curve.

The maximum speed at which a car traveling around a flat curve with constant speed will be able to negotiate the curve is primarily determined by the radius of curvature of the turn and the amount of friction between the road and the tires. The larger the radius of curvature, the higher the maximum speed the car can travel without slipping or losing control. Similarly, the greater the amount of friction between the road and the tires, the higher the maximum speed the car can travel. Other factors, such as the distance before the curve, can also affect the car's ability to negotiate the curve, but they are not as significant as the radius and friction.

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Network modifiers are elements or compounds that can alter the network structure of a ceramic glass by breaking the covalent bonds and introducing ionic bonds. The addition of network modifiers can decrease the glass transition temperature (Tg) of a ceramic glass.

Network modifiers are elements or compounds that can alter the network structure of a ceramic glass by breaking the covalent bonds and introducing ionic bonds. The addition of network modifiers can decrease the glass transition temperature (Tg) of a ceramic glass. This is because the introduction of ionic bonds disrupts the continuous network of covalent bonds, which lowers the energy required for the molecules to move and transition from a solid-like state to a liquid-like state. Therefore, the more network modifiers added to a ceramic glass, the lower the Tg will be. Conversely, the removal of network modifiers or the addition of network formers (elements or compounds that enhance the network structure) will increase the Tg of a ceramic glass.

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The diver will hit the water after 9/4 seconds.

To find the time when the diver hits the water, use the equation 16t² = 81. To find t, follow these steps:

1. Divide both sides of the equation by 16: t² = 81/16
2. Take the square root of both sides: t = √(81/16)
3. Simplify: t = 9/4 seconds


To calculate the velocity of the diver when they hit the water, use a = 9/4 seconds. The distance when the diver hits the water is d(a) = 16(9/4)² = 81 ft.

The velocity of the diver when they hit the water cannot be determined using the given information, as the limit expression for velocity is incomplete.

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The maximum instantaneous power consumption of the 120 V AC microwave oven that draws 8.5 A is 1.02 kW

The maximum instantaneous power consumption of the microwave can be calculated using the formula

P = VI, where P is power in watts, V is voltage in volts, and I is current in amperes.

Therefore, the maximum instantaneous power consumption of the microwave can be calculated as follows:
P = 120 V x 8.5 A = 1020 watts
To convert wats to kilowatts, we divide by 1000, so the maximum instantaneous power consumption of the microwave in kilowatts is:
P = 1020 watts / 1000 = 1.02 kW

Hence, the maximum instantaneous power consumption of the 120 V AC microwave oven that draws 8.5 A is 1.02 kW, which can be calculated using the theory of power being equal to voltage multiplied by current.

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The smallest distance x to a position where 650-nm light reflected from the top surface of the glass interferes constructively with light reflected from the silver coating on the bottom is 162.5 nm.

To determine the smallest distance x, we need to use the formula for constructive interference:
2d = mλ
where d is the distance traveled by each wave, λ is the wavelength of the light, and m is an integer representing the order of the interference.
In this case, we have two waves that are reflected: one from the top surface of the glass and one from the silver coating on the bottom. The light changes phase when reflected at the silver coating, which means that the reflected wave is shifted by half a wavelength (i.e., λ/2). This means that the distance traveled by each wave is different:
distance for wave reflected from top surface of glass = x
distance for wave reflected from silver coating = x + t/2
where t is the thickness of the glass.
We want the two waves to interfere constructively, so we need to find the smallest value of x that satisfies the equation 2d = mλ. Since we are dealing with two waves, we need to use the sum of the distances traveled by each wave:
2(x + t/2) - 2x = mλ
simplifying:
t = (mλ)/2
We can use this equation to find the thickness of the glass that satisfies constructive interference for different values of m (i.e., different orders of interference). The smallest value of t that satisfies constructive interference corresponds to the smallest value of m (i.e., m = 1), so:
t = (1)(650 nm)/2 = 325 nm
Now we can use this value of t to find the smallest distance x:
2(x + t/2) - 2x = λ
simplifying:
x = (λ - t/2)/2 = (650 nm - 325 nm/2)/2 = 162.5 nm

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The velocity vector has a magnitude of 8.0 m/s and a direction of 30° N of E can be expressed in unit vector notation as 6.93 î + 4.0 ĵ.

A velocity vector with a magnitude of 8.0 m/s and a direction of 30° North of East can be expressed in unit vector notation using the components of the vector in the x (east) and y (north) directions. To do this, we need to resolve the vector into its components using trigonometry.

The x-component of the velocity vector can be found using the cosine function:
Vx = magnitude * cos(angle)
Vx = 8.0 m/s * cos(30°)
Vx ≈ 6.93 m/s

The y-component of the velocity vector can be found using the sine function:
Vy = magnitude * sin(angle)
Vy = 8.0 m/s * sin(30°)
Vy ≈ 4.0 m/s

Now that we have the components of the velocity vector, we can express it in unit vector notation using the standard unit vectors for the x and y directions, which are î and ĵ, respectively. The velocity vector in unit vector notation is:

V = Vx î + Vy ĵ
V ≈ 6.93 î + 4.0 ĵ

So, the velocity vector with a magnitude of 8.0 m/s and a direction of 30° North of East can be expressed in unit vector notation as approximately 6.93 î + 4.0 ĵ. This representation makes it easier to analyze and manipulate the vector in mathematical calculations, such as finding the resultant velocity or other vector properties.

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The universe has three possible futures: an open universe, a closed universe, and a flat universe. The average density of matter in the universe, also known as the critical density, plays a significant role in determining which of these futures is correct because it directly affects the universe's expansion rate and overall geometry.

1. Open Universe: If the average density of matter is less than the critical density, the universe will expand forever, eventually becoming too sparse for gravitational forces to pull objects back together. This is an open universe, characterized by a negatively curved geometry.

2. Closed Universe: If the average density of matter is greater than the critical density, the universe will eventually stop expanding and contract due to the force of gravity. This leads to a closed universe, which has a positively curved geometry.

3. Flat Universe: If the average density of matter is exactly equal to the critical density, the universe will continue to expand but at a gradually slowing rate. This results in a flat universe with a geometrically flat, or Euclidean, geometry.

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The temperature of the mercury would increase by approximately 357.14°C when 100 J of heat energy is transferred to 20 g of mercury.

To calculate the temperature increase of the mercury, we need to know the specific heat capacity of mercury. The specific heat capacity of a substance is the amount of heat energy required to raise the temperature of one unit of mass by one degree Celsius.

For mercury, the specific heat capacity is 0.14 J/g°C.

Using this value, we can calculate the temperature increase of the mercury:

First, we need to convert the mass of mercury from grams to kilograms:

20 g = 0.02 kg

Next, we can use the formula:

Q = m x c x ΔT

where Q is the heat energy transferred, m is the mass of the substance, c is the specific heat capacity, and ΔT is the temperature change.

Substituting in the values we have:

100 J = 0.02 kg x 0.14 J/g°C x ΔT

Solving for ΔT:

ΔT = 100 J / (0.02 kg x 0.14 J/g°C)

ΔT = 357.14°C

Therefore, the temperature of the mercury would increase by approximately 357.14°C when 100 J of heat energy is transferred to 20 g of mercury.

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The phase difference between two waves (Δφ) is directly related to the extra physical distance (Δx) one wave travels compared to the other, and the wavelength of the waves (λ). Specifically, the phase difference is equal to the extra physical distance divided by the wavelength, or Δφ = 2π(Δx/λ). This relationship is important in understanding interference patterns and wave behavior in general.

The relationship between the phase difference (Δφ) between two waves, the extra physical distance one wave travels compared to the other (Δd), and the wavelength of these waves (λ) can be described by the following equation:

Δφ = (2π / λ) * Δd

This equation shows that the phase difference is directly proportional to the extra distance traveled by one wave and inversely proportional to the wavelength of the waves.

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In a metal conductor, the relationship between current and voltage is typically described by Ohm's Law, which states that the current (I) flowing through a conductor is directly proportional to the voltage.

.

(V) applied across it, and inversely proportional to the resistance (R) of the conductor. Mathematically, Ohm's Law can be expressed as:

V = I * R

where V is the voltage in volts, I is the current in amperes, and R is the resistance in ohms. This means that when the voltage across a metal conductor is increased, the current through the conductor will also increase, assuming the resistance remains constant. Similarly, when the voltage is decreased, the current will also decrease, again assuming the resistance remains constant. This linear relationship between current and voltage is a fundamental principle in electrical circuits and is widely used in the analysis and design of electronic systems.

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The answer  is option D) Nâ¢s2/m. This unit is used to express force and not mass.

The newton (option A), slug (option B), gram (option C), and kilogram (option E) are all units used to express mass in different systems of measurement. However, Nâ¢s2/m is the unit for momentum, which is a product of mass and velocity, and is therefore a unit of force and not mass.

The units used to express mass are B) slug, C) gram, and E) kilogram. The newton (A) is a unit of force, not mass, and D) N•s²/m is a derived unit for moment of inertia.

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Interstellar dust, dark nebulae, and the twinkling of stars are evidence visible to human eyes that suggest the spaces between stars are not totally empty.

Space between the stars is called the interstellar space. These spaces are not actually empty and result in some common phenomena visible to the human eye.

The presence of interstellar dust, which is made up of tiny particles that can scatter and absorb light, causes it to appear redder and dimmer than expected.

The observation of gas clouds, such as the dark nebulae appear as dark patches against the background of stars. These clouds are made up of gas and dust and can be detected through their absorption and emission of light.

Additionally, the presence of cosmic rays, which are high-energy particles that travel through space, also suggests that the space between stars is not completely empty.

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fs ≥ μsn, where fs is the force of static friction and μs is the coefficient of static friction. This means that the force of static friction is equal to or greater than the product of the coefficient of static friction and the normal force (n). The correct expression for the force of static friction is D.

The resistance people feel when they try to move something that is stationary on a surface without actually moving their bodies or the surface they are trying to move it on.

It can be explained as the frictional force that perfectly balances the applied force throughout the body's stationary state.

The static frictional force is self-regulating, meaning that it will always be equal to and the opposite of the applied force.

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To solve this problem, we need to use the Pythagorean theorem to find the distance between the two cars.

After two hours, the car traveling south will have gone 56*2 = 112 miles, and the car traveling west will have gone 42*2 = 84 miles. If we draw a right triangle with the two cars at the vertices of the right angle, then the distance between them is the hypotenuse of the triangle. Using the Pythagorean theorem, we have:

distance^2 = 112^2 + 84^2
distance^2 = 12,544 + 7,056
distance^2 = 19,600
distance = sqrt(19,600)
distance = 140 miles

To find the rate at which the distance between the cars is increasing, we need to take the derivative of the distance equation with respect to time. Since both cars are moving at a constant speed, we can use the chain rule to get:

d(distance)/dt = (d(distance)/dx) * (dx/dt) + (d(distance)/dy) * (dy/dt)

where x is the distance traveled by the car traveling west, y is the distance traveled by the car traveling south, and t is time. Taking the derivatives, we have:

d(distance)/dx = 2x/2(distance) = x/distance
d(distance)/dy = 2y/2(distance) = y/distance
dx/dt = 42 mph
dy/dt = 56 mph

Substituting in the values we know, we get:

d(distance)/dt = (84/140) * 42 + (112/140) * 56
d(distance)/dt = 0.6 * 42 + 0.8 * 56
d(distance)/dt = 25.2 + 44.8
d(distance)/dt = 70

Therefore, the rate at which the distance between the two cars is increasing two hours later is 70 miles per hour.

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The angular momentum of hydrogen atom in a 4p state is √2 ℏ.

The angular momentum of an atom is given by,

L = ℏ [√l(1 + l)]

where ℏ is the reduced Plank's constant and l is the orbital quantum number.

1) In 4p state, the value of l is 1.

Therefore, the angular momentum of hydrogen atom in a 4p state,

L = ℏ [√1(1 + 1)]

L = √2 ℏ

2) In 5f state, the value of l is 3.

Therefore, the angular momentum of hydrogen atom in a 5f state,

L = ℏ [√3(1 + 3)]

L = 2√3 ℏ

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Answer: Table B is best suited for recording the data, as it lists the temperature readings at regular intervals of two minutes. This will allow for a clear and organized record of the temperature change over time, making it easier to analyze and draw conclusions from the data.

Explanation:

The statement "Two free (not held fixed) point charges q and 4q are a distance l apart. A third charge is placed such that all three charges have zero acceleration" is true.

A third charge can be placed such that all three charges have zero acceleration. To achieve this, the third charge should be placed along the line connecting the two initial charges, closer to the charge with the smaller magnitude (q). The magnitude of the third charge will be equal to the square root of the product of the magnitudes of the two initial charges, i.e., √(q × 4q) = √(4q²) = 2q. The sign of the third charge will be opposite to the charge of q, as it needs to provide equilibrium to both charges.

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The predicted period of oscillation t is approximately 0.85 seconds.where F is the force applied to the spring and x is the displacement from equilibrium. In this case, we know that the mass hanging on the spring is 3 kg, and the displacement is 0.25 meters.

We also know that the force applied to the spring is given by:

F = mg

a) To calculate the spring constant k, we can use the formula:

k = F/x

where g is the acceleration due to gravity, which is approximately 9.81 m/s^2. Therefore:

F = 3 kg x 9.81 m/s^2 = 29.43 N

Now we can use the formula for k:

k = F/x = 29.43 N / 0.25 m = 117.72 N/m

So the spring constant k is 117.72 N/m.

b) To predict the period of oscillation t, we can use the formula:

t = 2π √(m/k)

where m is the mass hanging on the spring and k is the spring constant. In this case, we can ignore the mass of the spring itself, so we use m = 3 kg. Plugging in the value of k that we found in part a), we get:

t = 2π √(3 kg / 117.72 N/m) ≈ 0.85 seconds

So ,the predicted period of oscillation t is approximately 0.85 seconds.

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The force exerted by a spring with a stiffness of 100 N/m that was compressed by 0.02 m can be calculated using the formula F = kx.

where F is the force in newtons, k is the stiffness in newtons per meter, and x is the compression or extension in meters.

Substituting the given values, we get:

F = 100 N/m x 0.02 m
F = 2 N

Therefore, the force exerted by the spring is 2 N.

To find the force exerted by a spring with a stiffness of 100 N/m that was compressed at 0.02 m, we can use Hooke's Law. Hooke's Law states that the force exerted by a spring is equal to the product of its stiffness (k) and the displacement (x) from its equilibrium position:

Force (F) = k x X

Given the stiffness (k) is 100 N/m and the displacement (x) is 0.02 m, we can plug these values into the formula:

Force (F) = 100 N/m x 0.02 m

Now, simply multiply the values:

Force (F) = 2 N

Therefore, the force exerted by the spring is 2 Newtons (N).

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