how are wavelength and frequency of light related?group of answer choiceswavelength is double the frequencywavelength increases as frequency increaseswavelength is one-half of the frequencywavelength increases as the frequency decreases

The temperature rise produced by one pulse may not be as noticeable or may not even occur if the energy input is not sufficient to cause a measurable temperature change.

The temperature change produced by one pulse does not depend on how warm the water is.

When a pulse of energy is applied to a sample of water, it is absorbed by the water molecules and causes them to vibrate more quickly. This increased vibrational energy results in an increase in temperature of the water, known as the temperature rise. The temperature rise is dependent on the amount of energy that is applied, as well as the mass and specific heat capacity of the water.

The initial temperature of the water will not have an effect on the temperature rise produced by one pulse, as long as the temperature is above the freezing point and below the boiling point of water. This is because the temperature rise is determined solely by the energy applied to the water, and not by the initial temperature.

However, if the initial temperature of the water is near its boiling point or freezing point, the temperature rise produced by one pulse may not be as noticeable or may not even occur if the energy input is not sufficient to cause a measurable temperature change.

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The expansion of the universe does not directly affect the separation between two stars within our galaxy.

The expansion of the universe is a global phenomenon that affects the distance between galaxies on a cosmological scale, but it does not affect the distances between objects within galaxies.

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Materials can prevent heat from transferring to the skin, protecting it from burns.

The thermal properties of a material play a crucial role in determining its usefulness in various applications. For example, consider the case of a hot pad that is used to protect hands from hot surfaces such as a hot aluminum pan or a hot pyrex pan. Aluminum has a high thermal conductivity, which means that it can transfer heat more rapidly than Pyrex. As a result, the hot pad is more important when touching a hot aluminum pan than a hot Pyrex pan, even if they have the same temperature.

Similarly, the thermal properties of a material can also impact how cake or bread cooks in different materials. For example, aluminum conducts heat much faster than glass, which can result in more rapid and uneven baking of cakes or bread. Pyrex, on the other hand, has a lower thermal conductivity and is better suited for slow, even baking.

When it comes to frying pans, a good material choice would be one that has high thermal conductivity and heats up quickly, such as copper or aluminum. These materials allow for rapid heat transfer to the food being cooked, resulting in faster and more even cooking. A good hot pad material, on the other hand, would be one that has low thermal conductivity and acts as a good insulator, such as silicone or neoprene. These materials can prevent heat from transferring to the skin, protecting it from burns.

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By using the Pythagoras theorem to determine the height where Carolina should place the hook to hold the lights, we find that she should place them at a height of 12.81 ft.

Let us assume the points on the given triangle as following:

A = the point where the lights will be secured into the ground

B = the position where Carolina is standing, holding the lights

C = the point on the tree where the hook will be placed to hold the lights

D = the bottom of the tree trunk

Now, we want to determine the height of point C on the tree because we are aware that the length of the lights is feet long.

Using the Pythagoras theorem,

AB² + BC² = AC²

Since Carolina is 10 feet away from the tree, we know that AB = 10 feet, and BC = 8 feet because the lights are 8 feet long and we want them to hang straight down. We can change these numbers in the equation to:

=10² + 8² = AC²

=100 + 64 = AC²

= AC² = √164

= AC ≈ 12.81 feet

Therefore, Carolina should place the hook about 12.81 feet up the tree to hold the lights straight.

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A) The solution has a molarity of 0.1176 M.  B) The pipet contains 0.00353 moles of copper(II) nitrate and C) The new solution has a molarity of 0.0147 M.

A) Cu(NO3)2 has a molar mass of 187.55 g/mol.

Mass / molar mass = number of moles

5.52 g / 187.55 g/mol equals the number of moles.

Molecular weight: 0.0294 mol

Molarity is equal to the moles of solute per litre of solution.

250.0 mL = 0.2500 L

Molarity is equal to 0.0294 mol/0.2500 L.

Molarity equals 0.1766 M

The solution's molarity is 0.1176 M as a result.

B) The solution's molarity, which we determined in section (a):

Liquid volume divided by the molarity gives the moles of Cu(NO3)2

Molecules of Cu(NO3)2 are equal to 0.1176 M and 0.0300 L, respectively.

As a result, the pipet contains 0.00353 moles of copper(II) nitrate.

C) The solution has been reduced by a factor of 8 by Mrs. Mandochino (240.0 mL / 30.0 mL). The new molarity is thus 1/8 of the initial molarity:

Molarity = 0.0147 M / Molarity = 0.1176 M / 8

As a result, the new solution has a molarity of 0.0147 M.

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When the oscillation of the particles in a medium is parallel to the direction of the wave's motion, this type of wave is called a longitudinal wave.

In a longitudinal wave, the particles of the medium vibrate back and forth along the direction of the wave's motion, rather than moving perpendicular to it. This creates areas of compression and rarefaction in the medium, which travel through the medium as the wave moves.

A common example of a longitudinal wave is a sound wave. When sound is produced, it causes the air particles to vibrate back and forth in the same direction that the sound is traveling. As these vibrations travel through the air, they create areas of compression and rarefaction, which our ears perceive as sound.

Another example of a longitudinal wave is a seismic wave, which is produced by earthquakes and travels through the Earth's crust. Seismic waves cause the particles in the Earth's crust to vibrate back and forth parallel to the direction of the wave's motion.

Therefore, a longitudinal wave is a wave in which the oscillation of particles in the medium is parallel to the direction of the wave's motion. Sound waves and seismic waves are examples of longitudinal waves.

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The tension in cord 2 is half that of cord 1.

The tension in the strings provides the necessary centripetal force to keep the rocks moving in their circular paths. Since the rocks have the same mass and the same period of motion, the centripetal force required for both rocks is the same.

The centripetal force on a rock moving in a circle of radius r with speed v is given by:

[tex]F = mv^2/r[/tex]

where m is the mass of the rock.

For circle 1, the centripetal force is:

[tex]$F_1$[/tex] = [tex]mv^2/r1[/tex]

For circle 2, the centripetal force is:

F₂ = [tex]mv^2/r2[/tex]

Since the period of motion is the same for both rocks, the speed of the rocks in each circle is the same. Therefore, we can write:

F₁ = F2

Substituting the expressions for F₁ and F₂, we get:

[tex]mv^2/r1[/tex]=[tex]mv^2/r2[/tex]

Canceling the mass and rearranging, we get:

r2/r1 = 2

Therefore, the radius of circle 2 is twice that of circle 1.

To find the ratio of the tensions in the two cords, we can use the equation for centripetal force and rearrange to solve for the tension:

F = [tex]mv^2/r = T[/tex]

where T is the tension in the cord.

For circle 1, the tension is:

T₁ = [tex]mv^2/r1[/tex]

For circle 2, the tension is:

T₂ = [tex]mv^2/r2[/tex]

Substituting the expression for r₂/r₁, we get:

T₂/T₁= [tex](mv^2/r2) / (mv^2/r1) = r1/r2 = 1/2[/tex]

Therefore, the tension in cord 2 is half that of cord 1.

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The statement "There must be equal amounts of mass on both sides of the center of mass of an object" is true.

The center of mass is a point in an object where the mass is equally distributed on all sides.

It is the point at which an object would balance if it were placed on a pivot.

This is due to the equal distribution of mass around the center of mass, which ensures the object's stability.

Therefore, the statement "There must be equal amounts of mass on both sides of the center of mass of an object" is true.

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What you experienced is an example of an optical illusion known as the "relative motion illusion."

When you were looking out the window, your brain was interpreting the movement of the other train relative to your own train. When the other train was stationary or moving at the same speed as your own train, it appeared as though your train was not moving.

However, when the other train started moving faster or slower than your train, your brain perceived the change in relative motion and interpreted it as your own train moving.

The presence of the security guard on the platform, who appeared stationary throughout the experience, helped to re-orient your perception of motion and made you realize that it was just an illusion.

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The type of energy used by the muscles of larvae and pupae to dive down through water is chemical potential energy from their cells. When the muscles contract, the chemical energy stored in the cells is converted into mechanical work, which allows the larvae and pupae to move through the water. Since Larvae and pupae have muscles that allow them to move through the water. When these muscles contract, they convert the stored chemical energy in their cells into mechanical work, which allows the larvae and pupae to move through the water. This is an example of how chemical potential energy can be converted into kinetic energy, which is the energy of motion. Therefore, the type of energy used by the muscles of larvae and pupae to dive down through water is chemical potential energy from their cells.

The positive charge of 10⁻⁶C is placed on an insulating solid conducting sphere, the charges are acquired by the sphere by using Gauss law. Thus, option E is correct.

When a point charge is placed over the insulated solid sphere, the charges are accumulated uniformly on the outer surface of the sphere by means of Gauss law. It states that the electric flux throughout any closed surface is zero.

From the given option- A) The charges are uniformly distributed on the outer surface of the sphere and not throughout the sphere. From B) The electric field inside the sphere is zero. From C) Electric field increases with the decrease of distance, E= kQ / r². In D) When an insulated metal is brought near to it, it doesn't acquire any charge.

From E) When a second conducting sphere is connected by a  conducting wire to the first one, a charge gets transferred. The charges are transferred until the electric potential between the two spheres is the same.

Thus, the ideal solution is option E.

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According to the question the radius of the cylinder is 1.32 cm and the height of the cylinder is also 1.32 cm.

Radius is a term used to describe the distance from the center to the circumference of a circle. It can also be used to measure the distance from the center of a sphere to its surface. The radius is half of the diameter, which is the distance from one side of the circle or sphere to the other.

The surface area of a right circular cylinder can be calculated using the formula A = 2πrh + 2πr2, where r is the radius of the cylinder and h is the height of the cylinder. In this case, the radius of the cylinder is 1.32 cm and the height of the cylinder is also 1.32 cm. Plugging these values into the formula, we get: A = 2π(1.32) x (1.32) + 2π(1.32)2 = 6.25 cm2.

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When the block slides up the ramp to point p, the total mechanical energy of the block remains constant and the total mechanical energy of the block-earth system decreases.

What is mechanical energy?

Mechanical energy of a body is the sum of the Kinetic energy and potential energy.

As the block slides up the ramp to point P, its mechanical energy decreases due to the work done by gravity against the block's motion. This work is equal to the change in the block's potential energy, which is mgh, where m is the mass of the block, g is the acceleration due to gravity, and h is the height of the ramp.

At the same time, the block gains kinetic energy due to its motion up the ramp. This gain in kinetic energy is equal to the work done by the component of the block's weight parallel to the ramp, which is mgh sin(theta), where theta is the angle of the ramp with respect to the horizontal.

Therefore, the total mechanical energy of the block alone remains constant since the loss in potential energy is equal to the gain in kinetic energy.

However, the total mechanical energy of the block-earth system decreases as the block gains potential energy and the Earth gains an equal amount of potential energy in the opposite direction. This is because the block and Earth together form a closed system, and the total mechanical energy of a closed system remains constant only if there are no external forces acting on it. In this case, gravity is an external force that does work on the block and transfers energy to the Earth, causing a decrease in the system's total mechanical energy.

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When the block slides up the ramp to point p, the total mechanical energy of the block remains constant and the total mechanical energy of the block-earth system decreases.

The mechanical energy of a body is the sum of the Kinetic energy and potential energy.

The mechanical energy of the block diminishes as it slides up the ramp to point P due to the effort done by gravity against the block's motion. This effort is equivalent to the change in potential energy of the block, which is mgh, where m is the mass of the block, g is gravity's acceleration, and h is the height of the ramp.

Simultaneously, the block accumulates kinetic energy as it moves up the ramp. This increase in kinetic energy is equal to the work done by the block's weight component parallel to the ramp, which is much sin(theta), where theta is the ramp's angle with respect to the horizontal.

Therefore, the total mechanical energy of the block alone remains constant since the loss in potential energy is equal to the gain in kinetic energy.

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To increase the period of oscillation (T) in a horizontal mass-spring system, you can either increase the mass (M) or decrease the spring constant (K).

The time taken for an oscillating particle to complete one cycle of oscillation is known as the Period of oscillating particle.

To increase the period of oscillation (T) of a mass (M) placed on a spring with a spring constant (K) and pulled back a distance (x) on a frictionless surface, you can change one of the following factors:

1. Increase the mass (M): Increasing the mass will cause the period of oscillation to increase because the spring will take more time to complete one oscillation cycle.

2. Decrease the spring constant (K): Reducing the spring constant will make the spring less stiff, allowing the mass to oscillate more slowly, thus increasing the period of oscillation.

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Wave A has twice the amplitude, one-half the wavelength, and three times the frequency of wave B.

In a dispersive medium, the wave velocity depends on its frequency and wavelength. However, for an identical dispersive medium, the relationship between velocity (v), frequency (f), and wavelength (λ) remains constant: v = fλ.

Since wave A has one-half the wavelength and three times the frequency of wave B, their velocities will be the same through the identical dispersive medium. The amplitude does not affect the velocity of the wave.

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The speed of the water inside the hose is 0.625 m/s.

To find the speed of the water inside the hose, we can use the principle of conservation of mass. This principle states that the mass flow rate of the water entering the hose must be equal to the mass flow rate of the water leaving the nozzle.

We can write this equation as:
A1 * v1 = A2 * v2
where A1 is the cross-sectional area of the hose, v1 is the speed of the water inside the hose, A2 is the cross-sectional area of the nozzle, and v2 is the speed of the water leaving the nozzle.

First, we need to find the cross-sectional areas A1 and A2.

Since both the hose and the nozzle have circular cross-sections, we can use the formula:

A = π * (d/2)²

where d is the diameter.

For the hose (A1):
A1 = π * (2.0 cm / 2)² = π * (1.0 cm)² = π cm²

For the nozzle (A2):
A2 = π * (0.50 cm / 2)² = π * (0.25 cm)² = 0.0625π cm²

Now, we can substitute these values and the given speed of the water leaving the nozzle (v2 = 10 m/s) into the equation:
π cm² * v1 = 0.0625π cm² * 10 m/s

To solve for v1, divide both sides by π cm²:

v1 = (0.0625π cm² * 10 m/s) / π cm² = 0.625 m/s

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(a). The mass of the other body is: 4.4 kg. (b).  The speed of the two-body center of mass if the initial speed of the 2.2 kg body was 6.8 m/s is 2.27 m/s.

In an elastic collision, both momentum and kinetic energy are conserved. Using these principles, we can solve for unknowns in this problem:

(a) Let the mass of other body be m. From conservation of momentum, we have:

2.2 kg × 6.8 m/s = (2.2 kg + m) × 1.7 m/s

Solving for m, we get m = 4.4 kg.

(b) The velocity of center of mass is given by:

[tex]Vcm = (m1v1 + m2v2)/(m1 + m2)[/tex]

We know m2 = 4.4 kg and v2 = 0 m/s.

Substituting the given values, we get:

[tex]Vcm = (2.2 kg * 6.8 m/s)/(2.2 kg + 4.4 kg) = 2.27 m/s[/tex]

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if a sound wave creates a large amplitude of vibration of the basilar membrane near the oval window, it suggests that the sound wave has a high intensity or loudness.

The basilar membrane is a structure located in the cochlea of the inner ear, and it plays a critical role in the process of hearing. When sound waves enter the ear, they cause the basilar membrane to vibrate, which in turn causes the hair cells on the membrane to bend and generate electrical signals that are sent to the brain.

The amplitude of the vibration of the basilar membrane is related to the intensity or loudness of the sound wave. The maximum amplitude of the vibration of the basilar membrane occurs near the oval window, which is the point where the stapes bone of the middle ear attaches to the cochlea. This is because the oval window is the point of entry for sound waves into the inner ear, and the initial vibration caused by the sound wave is transmitted most efficiently to the cochlea at this point.

So, if a sound wave creates a large amplitude of vibration of the basilar membrane near the oval window, it suggests that the sound wave has a high intensity or loudness. This is because the sound wave is able to effectively transmit its energy to the basilar membrane at this point, causing a large displacement of the membrane and resulting in a strong signal being sent to the brain.

It's important to note that the frequency of the sound wave also plays a critical role in determining how the basilar membrane vibrates. The basilar membrane is tonotopically organized, which means that different regions of the membrane are sensitive to different frequencies of sound. The frequency of the sound wave determines which region of the basilar membrane will vibrate most strongly, and this information is used by the brain to determine the pitch or frequency of the sound.

Therefore, A sound wave that creates a large amplitude of vibration of the basilar membrane near the oval window suggests that it has a high intensity or loudness, as it effectively transmits its energy to the membrane, causing a strong signal to be sent to the brain. The basilar membrane is critical for the process of hearing, and its vibration is related to the intensity, frequency, and ultimately the perception of sound.

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On an average diet, the consumption of 10 liters of oxygen releases 120 kJ of energy. So, the correct answer is option e.

When 10 litres of oxygen are consumed, 120 kJ (kilojoules) of energy are released.

This is computed by dividing the volume of oxygen consumed (10 litres) by the amount of energy released (4.8 kcal or 4.2 kJ) per litre of oxygen ingested.

Therefore, 4.2 kJ x 10 liters, or 120 kJ, is the total energy released by the ingestion of 10 litres of oxygen. The body uses this energy for a number of metabolic processes, including digestion, respiration, and physical activity.

The body's primary energy source, ATP (adenosine triphosphate), is produced only using oxygen. In conclusion, using 10 litres of oxygen daily will result in the release of 120 kJ of energy.

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The audio frequency spectrum represents the range of frequencies that the human ear can interpret. Sound frequency is measured in Hertz (Hz) unit. This audible frequency range, in the average person at birth, is from 20Hz to 20000Hz, or 20 kHz. The audio frequency spectrum is also known as sound frequency spectrum.

The magnitude of the force of friction acting on the block is approximately 4.2 N. The correct answer is 3) 4.2 N.

To find the magnitude of the force of friction acting on the block, we can use the equation:

f_friction = m * (g * sin(θ) - a)

Where:
- f_friction is the force of friction
- m is the mass of the block (1.8 kg)
- g is the acceleration due to gravity (9.81 m/s²)
- θ is the angle of the inclined plane (10°)
- a is the acceleration of the block down the incline (3.8 m/s²)

f_friction = 1.8 * (9.81 * sin(10°) - 3.8)

Calculating this, we get:

f_friction ≈ 4.2 N

So, the magnitude of the force of friction acting on the block is approximately 4.2 N. The correct answer is 3) 4.2 N.

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Gravitational potential energy is always measured with respect to a particular height where its value is defined to be zero. In this case, the reference level is typically chosen as the ground or surface upon which the object rests. Therefore, the location of the ball where its gravitational potential energy would be zero is when it is resting on this reference level, such as the ground or surface.

The reference level for gravitational potential energy is typically chosen to be the height at which the object is at rest or ground level. Therefore, the gravitational potential energy of a ball would be zero when it is located at ground level or the reference height. Any height above this level would have a positive gravitational potential energy, indicating that the object has the potential to fall due to gravity. Conversely, any height below this level would have a negative gravitational potential energy, indicating that the object would require external energy to be lifted back up to the reference level.

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Passive force is generated in skeletal muscles when they are stretched beyond their resting length.

The range of skeletal muscle lengths that generate passive force is typically greater than the resting length, up to the maximum elongation the muscle can tolerate without tearing. This range is also known as the muscle's "physiological range of motion". The amount of passive force generated by the muscle increases as it is stretched further beyond its resting length, until it reaches a maximum at the point of muscle failure.

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The maximum kinetic energy and period of oscillation for a system of two blocks compared to those of a single block (block 1) will be greater, and the period of oscillation will likely be different due to changes in the combined mass and spring constant.

Maximum kinetic energy: In a system of two blocks, the total kinetic energy is the sum of the kinetic energies of both blocks.

The maximum kinetic energy of the system will be greater than that of block 1 alone since it will include the kinetic energy of the second block as well.

However, the distribution of kinetic energy between the two blocks will depend on their respective masses and velocities.

Period of oscillation: The period of oscillation for a system of two blocks depends on the combined mass, spring constant, and damping forces (if any) acting on the system.

The period of oscillation for the system with both blocks will likely be different from that of block 1 alone, as the total mass and effective spring constant will change.

Generally, an increase in mass will lead to a longer period of oscillation, while a stronger spring constant will result in a shorter period.

In summary, when comparing a system with two blocks to block 1 alone, the maximum kinetic energy will be greater, and the period of oscillation will likely be different due to changes in the combined mass and spring constant. The specific values will depend on the properties of the blocks and the spring(s) involved.

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For a given element, the black lines on an absorption spectrum appear at specific wavelengths.

Where the energy of the incoming light matches the energy required to excite electrons in the element's atoms from their ground state to higher energy levels. These wavelengths correspond to the specific electronic transitions that are possible within the element's atomic structure. Each element has a unique set of absorption lines that can be used to identify it, making absorption spectroscopy a powerful tool for chemical analysis and identification. For a given element, the black lines on an absorption spectrum appear at specific wavelengths corresponding to the energy levels of the element's electrons. These lines are called absorption lines and they occur when electrons absorb energy and transition from lower to higher energy levels.

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Yes, a braking torque is always negative and leads to a decrease in angular velocity. The given statement is true.

Torque is defined as the product of force and the lever arm, which is the perpendicular distance between the line of action of the force and the axis of rotation. Mathematically, torque can be expressed as:

τ = r × F

where τ is the torque, r is the lever arm, and F is the force.

When a braking torque is applied to an object, it is always opposite in direction to the direction of motion or rotation. The braking torque is applied to slow down or stop the rotation of the object. The direction of the torque is determined by the right-hand rule, which states that if you curl your fingers in the direction of the rotation of the object, then your thumb points in the direction of the torque. If the direction of the braking torque is opposite to the direction of the angular velocity, then the torque is negative.

The negative sign of the torque indicates that it is opposing the direction of the motion or rotation of the object. In other words, the braking torque acts to decrease the angular velocity of the object. The magnitude of the torque depends on the magnitude of the force and the distance between the force and the axis of rotation. A larger force or a greater lever arm will result in a larger torque and a greater slowing down of the object's rotation.

Therefore, a braking torque is always negative and leads to a decrease in angular velocity. It is the opposite of a driving torque, which is applied to increase the angular velocity of an object.

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An air conditioner with a coefficient of performance of 3.50 uses 30.0 KW of power to operate. 105 kW power is t discharged to the outdoors. Option(c)

The coefficient of performance (COP) for an air conditioner is defined as the ratio of the heat energy removed from the indoor air to the work input required to remove it. Thus, the amount of heat removed from the indoor air can be calculated as:

Heat energy removed = COP x Work input

Substituting the given values, we have:

Heat energy removed = 3.50 x 30.0 kW = 105 kW

Since the air conditioner removes heat from the indoor air and discharges it outdoors, the power discharged to the outdoors will also be 105 kW. Therefore, the answer is E. 105 kW.

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Answer: Sounds are made when objects vibrate. The vibration makes the air around the object vibrate and the air vibrations enter your ear, You hear them as sounds

Explanation:

This means that Q completes 41 oscillations while P completes 40 oscillations the answer is (A) 1 oscillation.

The pendulums will move in phase with each other when the time taken for each oscillation is an integer multiple of the common time period. Let T be the common time period between P and Q.

Then, the time taken for P to complete one oscillation is 1.90 s. Therefore, we have:

[tex]1.90 s = n * T[/tex], where n is an integer.

Similarly, the time taken for Q to complete one oscillation is 1.95 s, so:

[tex]1.95 s = m * T[/tex], where m is an integer.

To find the number of oscillations made by Q between two consecutive instants when P and Q move in phase with each other, we need to find the smallest integers n and m such that their ratio m/n is close to 1. Let's divide the second equation by the first:

[tex]1.95 s / 1.90 s = m * T / n * T[/tex]

Simplifying, we get:[tex]1.026 = m/n[/tex]

Now we need to find the smallest integers m and n such that m/n is close to 1.026. One way to do this is to use continued fractions. We have:

[tex]1.026 = 1 + 1/(1 + 1/40.15)[/tex]

Therefore, the best approximation for m/n is:

[tex]m/n = 41/40[/tex]

This means that Q completes 41 oscillations while P completes 40 oscillations. The number of oscillations made by Q between two consecutive instants when P and Q move in phase with each other is therefore:

[tex]41 - 40 = 1[/tex]

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