n a hydroelectric installation, a turbine delivers 1500 hp to a generator, which in turn converts 80% of the mechanical energy into electrical energy. under these conditions, what current will the generator deliver at a terminal potential difference of 2000 v?

In order to achieve constructive interference, the light waves passing through the two slits must arrive at the screen in phase. This means that the path difference between the waves must be equal to an integer multiple of the wavelength. The path difference can be expressed as d sinθ, where d is the distance between the two slits and θ is the angle that the light rays make with the horizontal line bisecting the slits.

Hence, in order to achieve constructive interference, the condition is that d sinθ = mλ, where m is an integer representing the number of wavelengths that fit into the path difference. Therefore, the value of θ that satisfies this condition will result in interference maxima being seen on the screen.In interference, a maximum is a point when two crests or two troughs of two separate waves collide and reinforce one another. Minima in interference, on the other hand, is a point where a crest and a trough meet and cancel each other out.

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Answer:

If you are standing on a scale in an elevator and suddenly notice that your weight decreases, it means that the elevator is accelerating downwards. When the elevator accelerates downwards, there is a decrease in the normal force acting on you, which is the force that the scale measures as your weight.

According to Newton's second law of motion, the net force acting on an object is equal to its mass times its acceleration. In this case, the net force acting on you is the force of gravity pulling you downwards minus the normal force pushing you upwards. When the elevator accelerates downwards, the normal force acting on you decreases, and therefore the net force acting on you decreases as well. Since your mass remains constant, a decrease in net force results in a decrease in acceleration, which is what the scale measures as a decrease in your weight.

Therefore, if you notice your weight decreasing while standing on a scale in an elevator, you can conclude that the elevator is accelerating downwards.

Explanation:

The weight of a 2.50-kg bag of sand on the surface of the earth is 24.5 N (Option C). This is because weight is equal to mass multiplied by the acceleration due to gravity (w = mg), and on the surface of the earth, the acceleration due to gravity is approximately 9.80 m/s2. Therefore, the weight of the bag is 2.50 kg x 9.80 m/s2 = 24.5 N.

To calculate the weight, you need to use the following formula: Weight (W) = mass (m) + acceleration due to gravity (g)

Given:
Mass (m) = 2.50 kg
Acceleration due to gravity (g) = 9.80 m/s2
Now, apply the formula:
W = 2.50 kg, 9.80 m/s2.
W = 24.5 N

So, the weight of a 2.50-kg bag of sand on the surface of the earth is 24.5 N, which corresponds to option C in your choices.

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The starting of a snowboarder's motion is explained by Newton's third law of motion.

According to this law, every action has an equal and opposite reaction. Thus, forces always operate in pairs.

The first object exerts force, which is the person's foot pushing against the ground. The snowboarder then experiences a pushback from the ground as a result of the equal and opposite reaction force on the foot. The ground's reaction propels the person forward. Always of equal magnitude to the action force, the response force acts in the opposite direction.

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Answer:

The answer for Work done is 64J or 64Nm

Explanation:

W=F×D

F=ma

F=mg

F=0.16×10=1.6N

W=F×D

W=1.6×40

W=64J or 64Nm

the child will be 5.00 m away from the pier when he reaches the far end of the boat.When the child walks to the far end of the boat, the boat will experience a shift in its center of mass. Since both the child and the boat have the same mass of 40.0 kg, the center of mass of the system will move towards the child's initial position.

When the child walks to the far end of the boat, the boat will experience a shift in its center of mass. Since both the child and the boat have the same mass of 40.0 kg, the center of mass of the system will move towards the child's initial position.

To find the new position of the center of mass, we can use the formula:

x_cm = (m_1x_1 + m_2x_2) / (m_1 + m_2)

where x_cm is the position of the center of mass, m_1 and m_2 are the masses of the child and the boat respectively, and x_1 and x_2 are their initial positions relative to the pier.

Plugging in the given values, we get:

x_cm = (40.0 kg * 3.00 m + 40.0 kg * 1.00 m) / (40.0 kg + 40.0 kg)

x_cm = 2.00 m

Therefore, when the child reaches the far end of the boat, the center of mass of the system will be 2.00 m away from the pier, and the child will be at a distance of 4.00 m from the pier (the length of the boat) plus the distance he walked to get there. The final position of the child relative to the pier will be:

4.00 m + 1.00 m = 5.00 m

So, the child will be 5.00 m away from the pier when he reaches the far end of the boat.

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Answer:

C) 3m/s

Explanation:

f = ma

6N = 2kg×a

a = 6N / 2kg

a= 3m/s

The lost in kinetic energy after the collision is 55.45 J.

The kinetic energy lost after collision is calculated as follows;

Their final velocity after the collision is calculated as;

(80 + 30) v = 100 kgm/s

110v = 100

v = 100/110

v = 0.91 m/s

The sum of their initial velocity before and after collision;

K.Ei = 0.5 x (30)(2²) + 0.5 x (80)(1²)

K.Ei = 100 J

K.Ef = 0.5(30 + 80)(0.9²)

K.Ef = 44.55 J

ΔE = 100 J - 44.55 J

ΔE = 55.45 J

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If the coefficient of static friction between the tires and the road is doubled, it means that the frictional force keeping the car from sliding will also increase.

Therefore, it is possible that the car will be able to make the turn with less slipping and at a higher speed. It is also possible that the car will require less force to make the turn, as the increased frictional force will provide more grip and stability. However, it is important to note that other factors, such as the weight distribution of the car and the sharpness of the turn, may also affect the car's ability to make the turn safely.

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The maximum elongation of Earth as seen from Mars, we need to understand the concept of elongation. Elongation is the angle between a planet and the Sun as observed from another celestial body. In this case, we are observing Earth's elongation from Mars.

The maximum elongation occurs when the two planets are at their closest approach in their respective orbits. This is called opposition. During opposition, Earth and Mars are on opposite sides of the Sun, which results in the largest possible elongation.

To calculate the maximum elongation, we can use the following steps:

1. Determine the average distance between Earth and Mars at opposition. This is approximately 54.6 million kilometers (33.9 million miles).

2. Calculate the angle between Earth, Mars, and the Sun using the Law of Cosines. The formula for this is:
cos(E) = (a^2 + b^2 - c^2) / (2ab)

where E is the elongation angle, a is the distance from Mars to the Sun, b is the distance from Earth to the Sun, and c is the distance between Earth and Mars.

3. Plug in the values for a, b, and c. The average distance from Mars to the Sun is 227.9 million kilometers, and the distance from Earth to the Sun is 149.6 million kilometers.
cos(E) = ((227.9^2) + (149.6^2) - (54.6^2)) / (2 * 227.9 * 149.6)

4. Solve for E:
E ≈ 46.8 degrees

So, the maximum elongation of Earth as seen from Mars is approximately 46.8 degrees.

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To answer this question, we need to consider a circuit with a resistor and a capacitor connected in series, driven by an AC source.

At a certain frequency, the voltage across the resistor will be at its maximum. This is known as the resonant frequency of the circuit. At the resonant frequency, the voltage across the capacitor will be equal to the voltage across the resistor. This is because the capacitor and resistor will be in phase at this frequency, and the voltage drop across each component will be equal. So, if we know the voltage across the resistor at the resonant frequency, we can say that the voltage across the capacitor is also that same value. We just need to make sure we express our answer with the appropriate units. The AC voltage will be in volts (V).

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The moment of inertia about an axis perpendicular to the rod and passing through its center is [tex]0.00900 kg m^2[/tex], passing through one end is [tex]0.0180 kg m^2[/tex] along the length of the rod is [tex]1.21 * 10^{-6} kg m^2[/tex]

A. To find the moment of inertia about an axis perpendicular to the rod and passing through its center, we can use the formula[tex]I = (1/12) * m * L^2[/tex], where m is the mass of the rod, L is the length of the rod, and I is the moment of inertia. Substituting the values given in the problem, we get:
I = [tex](1/12) * 0.0500 kg * (1.20 m)^2 = 0.00900 kg m^2[/tex]
B. To find the moment of inertia about an axis perpendicular to the rod and passing through one end, we can use the formula [tex]I = (1/3) * m * L^2[/tex], where m is the mass of the rod, L is the length of the rod, and I is the moment of inertia. Substituting the values given in the problem, we get:
I = [tex](1/3) * 0.0500 kg * (1.20 m)^2 = 0.0180 kg m^2[/tex]
C. To find the moment of inertia about an axis along the length of the rod, we can use the formula [tex]I = (1/4) * m * r^2[/tex], where m is the mass of the rod and r is the radius of the rod (which is half of the diameter). Substituting the values given in the problem, we get:
r = 0.220 cm / 2 = 0.0110 m
I = [tex](1/4) * 0.0500 kg * (0.0110 m)^2 = 1.21 * 10^{-6} kg m^2[/tex]

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If unpolarized light is passed through an optical filter that is oriented in the vertical direction, the intensity of the light that emerges from the filter will depend on the polarization axis of the filter. If the filter is perfectly oriented in the vertical direction, it will only allow light with vertical polarization to pass through and block all other polarizations.

Assuming the filter is perfectly oriented in the vertical direction, the intensity of the light that emerges from the filter can be calculated using Malus's law, which states that the intensity of polarized light passing through a polarizer is proportional to the square of the cosine of the angle between the polarization direction of the light and the axis of the polarizer.

In this case, the angle between the polarization direction of the unpolarized light and the vertical axis of the filter is 0 degrees, so the cosine of the angle is 1. Therefore, the intensity of the light that emerges from the filter is equal to the incident intensity of the unpolarized light times the square of the cosine of the angle, or:

Intensity of light that emerges from the filter = (86 w/m2) x (cos 0)2 = 86 w/m2

So, the intensity of the light that emerges from the filter is 86 w/m2, expressed to two significant figures.

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A multi-grounded circuit is a circuit that has more than one point connected to earth ground, with a voltage potential difference between the two ground points.

A multi-grounded circuit is an electrical circuit that has more than one grounding conductor or path to ground. Grounding is an important safety measure in electrical systems, as it provides a low-impedance path for fault currents to flow to ground, which helps to prevent electrical shocks, fires, and equipment damage.

In a multi-grounded circuit, there are multiple grounding conductors that are connected to the earth or a common ground point. This is done to provide redundancy in case one of the grounding paths becomes compromised or fails.

For example, in a typical residential electrical system, the main panel may have a grounding electrode conductor that connects to a grounding rod or other grounding device outside the home. However, individual circuits within the home may also have their own grounding conductors that connect to the main panel. This creates a multi-grounded system, with multiple paths for fault currents to flow to ground.

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The angular acceleration (α) of the slotted arm AB based cannot be determined on the information given.

To determine the angular velocity and angular acceleration of the slotted arm AB at the instant shown, follow these steps:

Identify the given information: The counterclockwise angular velocity of 4 rad/s is provided.

Calculate the angular velocity: Since the angular velocity is given as counterclockwise and equal to 4 rad/s, the angular velocity (ω) of the slotted arm AB is also 4 rad/s in the counterclockwise direction.

Determine the angular acceleration: The problem statement does not provide any information about the rate of change of angular velocity or any forces acting on the system. Therefore, we cannot determine the angular acceleration (α) of the slotted arm AB based on the information given. Additional information is needed to calculate angular acceleration.

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Energy known as radiation travels from one location to another in the form of waves or particles.

Thus, Radiation is a constant in our daily lives. The sun, the microwaves in our kitchens, and the radios we use in our cars are a few of the most well-known sources of radiation.

Our health is not at risk from the majority of this radiation. However, some do.

Radiation generally has a lesser danger at lower doses but a higher risk at higher ones. Different precautions must be taken depending on the type of radiation in order to shield our bodies and the environment from its effects while yet enabling us to take use of its numerous applications.

Thus, Energy known as radiation travels from one location to another in the form of waves or particles.

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In the photoelectric effect, the maximum speed of electrons emitted by a metal surface when it is illuminated by light depends on two factors: ii) frequency of light and iii) nature of the photoelectric surface. Therefore, the correct answer is "II and III only".

The maximum speed of emitted electrons is not directly affected by the intensity of light (i). Instead, the intensity affects the number of electrons emitted but not their speed. The frequency of light (ii) plays a crucial role in determining the maximum speed because higher frequencies provide more energy to the electrons, overcoming the work function of the metal and allowing them to be emitted with higher kinetic energy. This relationship is described by the Einstein's photoelectric equation: Ek = hf - φ, where Ek is the maximum kinetic energy of the electron, hf is the energy of the incident photon, and φ is the work function of the metal.

The nature of the photoelectric surface (iii) also plays a role as different materials have different work functions, which affect the energy required to release electrons. Thus, the maximum speed of emitted electrons depends on both the frequency of light and the nature of the photoelectric surface. Hence, the correct answer is both ii) frequency of light and iii) nature of the photoelectric surface.

The question seems incomplete, it must have been:

"In the photoelectric effect, the maximum speed of electrons emitted by a metal surface when it is illuminated by light depends on which of the following? i) intensity of light ii) frequency of light iii) nature of the photoelectric surface

I only

III only

I and II only

II and III only

I, II, and III only"

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0.679R is the height of the ball, that is on the verge of leaving the track when it reaches the top of the loop. 0.391 N is the magnitude.  The direction of the component is along the centripetal acceleration.

Mass of brass ball = 0 .280g

Radius = 14.0 cm

(a) kinetic energy = 1/2 [tex]mv^2[/tex]

In the bottom loop, the potential energy is thoroughly converted into kinetic energy. So the kinetic energy will be:

m*g*h = 1/2[tex]mv^2[/tex]

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

At the top, the total energy of the ball is equal to the potential energy at the bottom of the loop.

mgh = 1/2 [tex]mv^2[/tex]+ mgh_n

h_n = R - r - 1/2*([tex]v^2/g[/tex])

h_n = R - 14 - 1/2*([tex]v^2/g[/tex]) = 0.549R

h = h_n + r = 0.679R

(b) To find the magnitude of the horizontal force, we need to utilize the centripetal force equation:

F_c = m a_c = m [tex]v^2[/tex]/R

F_h = F_c - mg

F_h = (0.280 g)(2gh/R) - (0.280 g)(9.8 [tex]m/s^2[/tex])

F_h= 0.391 N

(c) The direction of the horizontal force component is toward the center of the loop. It is along with the direction of centripetal acceleration.

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The wavelength of an electron with a mass of 9.11 × 10-28 g moving at 1/5 the speed of light is approximately 3.28 × 10^-12 meters.

This can be calculated using the de Broglie wavelength formula:

λ = h/mv, where λ is the wavelength,

h is Planck's constant, m is the mass of the electron, and v is its velocity.

electron moving at 1/5 the speed of light  
3.28 × 10^-12 meters

Hence, the wavelength of an electron moving at 1/5 the speed of light can be found using the de Broglie wavelength formula and is approximately 3.28 × 10^-12 meters.

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The value of the capacitance is approximately 3.98 × 10^-10 F, which is closest to option (D) 4.8 × 10^-10 F. Therefore the correct option is option D.

We can use the following formula to calculate the capacitance of a parallel-plate capacitor:

C = ε0 * A / d

where C is capacitance, 0 is free space permittivity, A is the area of each plate, and d is the distance between the plates.

The plates have a surface area of 9 cm2, which is comparable to 9 * 10-4 m2. The distance between the plates is also reported as 2 mm, which is comparable to 2 * 10-3 m.

When we enter these values into the formula, we get:

[tex]C = (8.85 × 10-12 F/m * 9 * 10 - 4 m2) / (2 × 10-3 m)[/tex]

When we simplify, we get:

[tex]C = 3.98 * 10-10 F[/tex]

As a result, the capacitance is around 3.98 10-10 F, which is near to option (D) 4.8.

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The available fault current for the 2% impedance transformer will be closer to the infinite primary fault current than the 5% impedance transformer.

To determine the available fault current at the secondary of a service transformer, we can use the formula:
Available Fault Current = (Infinite Primary Fault Current) / (Impedance + Transformer Impedance Tolerance)
Given a 500 kVA, 3-phase, 480-volt (secondary) transformer with a 5% impedance and a 10% impedance tolerance (0.9 multiplier), we can plug these values into the formula as follows:
Available Fault Current = (Infinite Primary Fault Current) / (0.05 + 0.05 x 0.9) = (Infinite Primary Fault Current) / 0.095
We are not given a value for the infinite primary fault current, but we are given the equation j444lm.l1 l05 e005 which is not relevant to this calculation.
Moving on to the second part of the question, if we are given a 2% impedance instead, we can repeat the calculation as follows:
Available Fault Current = (Infinite Primary Fault Current) / (0.02 + 0.02 x 0.9) = (Infinite Primary Fault Current) / 0.038
Comparing the two equations, we can see that the available fault current will be higher with a lower impedance. However, without knowing the value of the infinite primary fault current, we cannot determine the exact available fault current for either scenario.

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You would need to increase the height of the piston to decrease the pressure inside the cylinder while keeping the temperature constant.

This is because the pressure and volume of a gas are inversely proportional, meaning that as one increases, the other decreases, as long as the temperature is constant. Therefore, by increasing the volume of the gas, you would be decreasing the pressure. It is important to note that this change would need to be made slowly and carefully to avoid any sudden changes in pressure or temperature.

To further explain this, when the gas is confined to a cylinder with a movable piston, the pressure of the gas is determined by the force exerted by the gas molecules on the walls of the cylinder. If the volume of the cylinder decreases, the gas molecules will have less space to move around in, and they will collide more frequently with the walls of the cylinder, resulting in an increase in pressure. Conversely, if the volume of the cylinder increases, the gas molecules will have more space to move around in, and they will collide less frequently with the walls of the cylinder, resulting in a decrease in pressure.

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The total distance the vehicle travels during this time interval is E. 50 m

To calculate the total distance traveled by the vehicle during the 5.0 s interval, we can use the equation for the uniformly accelerated motion:

distance = initial_velocity * time + 0.5 * acceleration * [tex]time^2[/tex]

Since the vehicle starts from rest, the initial_velocity is 0 m/s. Given an acceleration of 4.0 m/s² and a time interval of 5.0 s, we can plug these values into the equation:

distance = 0 * 5.0 + 0.5 * 4.0 * [tex]5.0^2[/tex]

distance = 0 + 0.5 * 4.0 * 25

distance = 0 + 50

Therefore, the total distance traveled by the vehicle during this time interval is 50 m (Option E).

The Question was Incomplete, Find the full content below :

Starting from rest, a vehicle accelerates on a straight level road at the rate of 4.0 m/s2 for 5.0 s.

What is the total distance the vehicle travels during this time interval?
A. 10 m
B. 20 m
C. 25 m
D. 40 m
E. 50 m

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Please see the attached image for the solution:

The induced current moves in a clockwise direction.

Induced current is formed in a conductor as a result of a change in the magnetic flux flowing through the area.

The magnetic field vector in the conducting loop is pointing straight up.

A current is induced in the magnetic field as a result of the constant strength increase.

The induced current moves in a clockwise direction when seen from above.

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The false statement is all three vehicles are accelerating.

It is given that all the vehicles are travelling at 40 miles per hour. So, they are having the same speed.

From the diagram, it is shown that,

The truck is turning to the right. So, we can say that the direction of motion of the truck is changing. That means, the velocity changes in the direction but, not in magnitude.

Therefore, the truck is accelerating.

The other two vehicles are travelling at constant velocity.

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Answer:

All three vhicles are accelerating.

Explanation:

Acceleration is a change in speed. It doesn't matter if the object is slowing down or speeding up, as long as the speed is changing it is accelerating.

The flow of water through the connecting tube is largest when the difference in energy density between the two containers is at its maximum.

According to the energy-density model for fluid flow, a larger difference in energy density results in a higher flow rate.
At the beginning, when the difference in water levels (and thus energy density) between the two containers is greatest, the flow rate is the highest. As the water levels equalize, the difference in energy density decreases, and the flow rate diminishes. When the energy density is equal in both containers, there is no flow.
So, the flow of water is not the same at all times. It is largest when the difference in energy density between the two containers is at its maximum and decreases as the energy density difference decreases.

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Venus experiences the smallest range of temperature among the planets in our solar system.

Venus experiences the smallest range of temperature because of its thick atmosphere, which is primarily composed of carbon dioxide and other greenhouse gases. These gases trap the heat from the Sun, creating a strong greenhouse effect that keeps the planet's surface temperature consistently high.

The thick atmosphere also circulates the heat around the planet, preventing large temperature fluctuations between day and night or between different regions. As a result, Venus has a very small range of temperature, with a surface temperature of around 462 °C (864 °F) that remains consistent both day and night.

Therefore, Of the planets in our solar system, Venus has the smallest temperature range.

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The ratio of the potentials of these surfaces is 1.2,

Option choice C is correct.

The potential at any point on an equipotential surface is constant.

Since both spheres are equipotential surfaces, the potential at the center of sphere A is equal to the potential at any point on sphere A, and likewise for sphere B.
The potential at the center of sphere A due to the point charge is given by the formula

V = kq/r,

where k is the Coulomb constant,

q is the charge,

and r is the distance from the charge to the point.

In this case,

V = kq/RA.
The potential at the center of sphere B due to the point charge is given by the same formula,

but with r = RB.

So V = kq/RB.
Taking the ratio of these two potentials, we get:
VA/VB = (kq/RA)/(kq/RB)
VA/VB = (RB/RA)
VA/VB = 0.0012/0.0010
VA/VB = 1.2.

Option choice C is correct.

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The magnitude of the frictional force acting on the block is 2 N since  the frictional force will exactly oppose the applied force. Answer is  B) 2 N

To determine the magnitude of the frictional force acting on the block, we need to use the coefficient of static friction (μs) and the normal force (N). The formula for calculating the maximum static frictional force (F_friction) is:

F_friction = μs * N

First, let's find the normal force. In this case, the normal force (N) is equal to the weight of the block, which is given as 10 N.

Now, let's use the given coefficient of static friction, which is 0.56. Plug the values into the formula:

F_friction = 0.56 * 10 N
F_friction = 5.6 N

Since the applied force (2.0 N) is less than the maximum static frictional force (5.6 N), the block will not move, and the frictional force will exactly oppose the applied force. Therefore, the magnitude of the frictional force acting on the block is: B) 2 N

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