an airplane accelerates at a constant speed at 30m/s2

In a first-class lever, the effort force and the load force act on opposite sides of the fulcrum, and the lever arm of each force is the perpendicular distance from the force to the fulcrum. The ideal mechanical advantage (IMA) of the lever is the ratio of the distance from the fulcrum to the effort force and the distance from the fulcrum to the load force.

IMA = distance from fulcrum to effort force / distance from fulcrum to load force

In this case, the distance from the fulcrum to the load force is 4 meters, and the distance from the fulcrum to the effort force is 15 meters. Therefore, the IMA of the lever is:

IMA = 15 m / 4 m = 3.75

The input work (Win) is the product of the effort force and the distance the effort force moves:

Win = effort force x distance moved by effort force

In this case, the effort force is 150 N, and it moves a distance of 15 meters. Therefore, the input work is:

Win = 150 N x 15 m = 2,250 J

The output work (Wout) is the product of the load force and the distance the load force moves:

Wout = load force x distance moved by load force

In this case, the load force is 350 N, and it moves a distance of 4 meters. Therefore, the output work is:

Wout = 350 N x 4 m = 1,400 J

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The work done by this gravitational force during a short time interval in which the earth moves through a displacement in its orbital path is zero.

The work done by a force is given by the dot product of the force and the displacement. In this case, the gravitational force is acting inwards towards the center of the circle, and the displacement is in the direction tangent to the circle. Since these two directions are perpendicular, the dot product of the force and the displacement is zero.

This is because the force is always perpendicular to the displacement of the Earth, and so the angle between the force and the displacement is always 90 degrees, which makes the dot product of the force and the displacement equal to zero.

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A student can determine whether a collision between two blocks is elastic or inelastic by examining the motion of the blocks before and after the collision.

In an elastic collision, the kinetic energy of the system is conserved, meaning that the total kinetic energy before the collision is equal to the total kinetic energy after the collision. This results in the blocks bouncing off each other and moving away with different velocities.

In an inelastic collision, some of the kinetic energy is lost as heat, sound, or deformation of the objects involved in the collision. This results in the blocks sticking together after the collision and moving away with the same velocity.

To determine whether the collision is elastic or inelastic, the student can measure the velocity of the blocks before and after the collision using a stopwatch and a ruler. If the velocity of the blocks after the collision is different from the velocity before the collision, then the collision is elastic. If the velocity of the blocks after the collision is the same as the velocity before the collision, then the collision is inelastic.

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A truck with a mass of 2500 kg travelling with an acceleration of 5 m/s2 hits a stationary scooter of mass 100 kg.  The acceleration of the scooter will be 125 m/s².

The acceleration of the scooter after the collision can be found using the conservation of momentum principle.

Initial momentum of the system = Final momentum of the system

Initial momentum = (mass of truck * initial velocity of truck) + (mass of scooter * initial velocity of scooter)

Final momentum = (mass of truck * final velocity of truck) + (mass of scooter * final velocity of scooter)

Since the scooter is initially stationary, its initial velocity is 0. We know the mass of the truck (2500 kg) and its acceleration (5 m/s²). To find its initial velocity, we need to determine the force acting on the truck:

Force = mass * acceleration

Force = 2500 kg * 5 m/s² = 12500 N

Now, we know that the force acting on the truck is equal to the force acting on the scooter (Newton's third law).

So, we can find the acceleration of the scooter:

Force = mass of scooter * acceleration of scooter

12500 N = 100 kg * acceleration of scooter

Acceleration of scooter = 12500 N / 100 kg = 125 m/s²

Thus, the acceleration of the scooter after the collision will be 125 m/s².

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The rider will begin with some potential energy and kinetic energy at the base of the hill, and they will end with only potential energy at the top. If the rider drives at a speed of 14 m/s, he can stop after reaching the top of the hill.

To determine the speed required for the rider to reach the top of the hill and stop, use the concept of the conservation of energy. The formula for potential energy is mass times gravity times height (PE=mgh).Since the hill is perfectly smooth, the work done by friction can be ignored. The kinetic energy of the sled-rider system is given by KE = 1/2 mv², where m is the mass of the system and v is the speed of the sled-rider system.

To reach the top of the hill and stop, the kinetic energy of the sled-rider system at the base of the hill must be equal to the potential energy of the system at the top of the hill. Therefore,1/2 mv² = mgh. Solve for v: v = √(2gh). Substitute the given values for h and g, h = 10 m and g = 9.8 m/s²v = √(2 x 9.8 m/s² x 10 m) = √(196) = 14 m/s. Therefore, the rider must have a speed of 14 m/s in order to reach the top of the hill and stop.

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Answer:

the answer is 71.61°

Explanation:

sorry if im wrong

The evolution of a gas, precipitate formation, color change, temperature change, and state change are significant aspects of chemical reaction.

A chemical reaction occurs when one or more substances completely transform into another one or more substances. It can exhibit one or more characteristics, such as a state change, color change, gas evolution, temperature change, precipitate development, etc. The majority of our energy is produced by chemical reactions. Many different types of materials are tested, identified, and studied using chemical reactions.

Combustion reaction, decomposition reaction, neutralization reaction, redox reaction, precipitation or double-displacement reaction, and synthesis reaction are some of the numerous types of reactions.

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What are the characteristics of chemical reactions?

The homogeneous portion of a mixture that is characterized by uniform properties and capable of being separated by mechanical means is called a phase.

A phase's physical and chemical characteristics can be used to determine whether it is a solid, liquid, or gas. Phase separation can be accomplished mechanically via centrifugation, filtration, or sedimentation.

In several disciplines, including chemistry, biology, and engineering, the ability to separate phases is crucial because it enables the separation and purification of desired components from mixtures. The word "homogeneous" describes a phase in which the components are spread uniformly.

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The complete question is

A homogeneous portion of a mixture that is characterized by uniform properties and capable of being separated by mechanical means is called a _____.

product

phase

reactant

solvent

Answer:

(c) 250

Explanation:

We can start by analyzing the horizontal and vertical motion of the ball separately. Since the ball is projected horizontally, its initial vertical velocity is 0.

Horizontal motion:

Initial horizontal velocity (Vx) = distance/time = 1 km / 4 s = 250 m/s

Final horizontal velocity (Vx) = same as initial velocity, since there is no horizontal acceleration

Vertical motion:

Initial vertical velocity (Vy) = 0

Vertical acceleration (a) = -9.8 m/s^2 (assuming downward direction as negative)

Time of flight (t) = 4 s

Final vertical velocity (Vy) = Vy + a*t = -9.8 m/s^2 * 4 s = -39.2 m/s

Vertical displacement (h) = Vyt + 0.5at^2 = 0 + 0.5(-9.8 m/s^2)*(4 s)^2 = -78.4 m (negative because the ball is falling below the initial height)

Now, we can use the Pythagorean theorem to find the height of the cliff:

h^2 + d^2 = (78.4 m)^2

h^2 + (1000 m)^2 = (78.4 m)^2

h^2 = (78.4 m)^2 - (1000 m)^2

h^2 = 61344 m^2

h = sqrt(61344 m^2) = 248 m

Therefore, the height of the cliff is approximately 248 m. The closest option is (c) 250.

The wheel 1 that rolls down the slope will reach the bottom first.

This is because when a wheel rolls, its kinetic energy is a combination of its translational kinetic energy (due to its linear motion) and its rotational kinetic energy (due to its rotation around its center). When the wheel rolls down the slope, some of its potential energy is converted to translational and rotational kinetic energy. The rolling motion allows the wheel to convert more of its potential energy into translational kinetic energy, which makes it move faster than a wheel that only slides down the slope without rolling.

On the other hand, the wheel that slides down the slope without rolling will only have translational kinetic energy, which means it will move slower than the rolling wheel. The negligible friction on the sliding wheel will not make a significant difference in its speed.

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The ball will go up to a height of 270.75 feet.

As per the question, a ball is thrown vertically upward from a height of 6 feet with an initial velocity of 60 feet per second. How high will the ball go?The ball's velocity in the upward direction,

v = 60 feet per second.Initial velocity,

u = 0 (because the ball starts from rest)The ball's initial position,

s = 6 feetThe acceleration due to gravity

, a = -32 feet per second squared (because the ball is moving upward against the force of gravity)We can determine the maximum height attained by the ball using the following formula:

S = (v^2 - u^2) / 2a + sPut the values in the formula,

S = (60^2 - 0^2) / 2(-32) + 6= 270.75 feet

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The movement of air masses across North America from west to east is consistent with global flow of wind over the continent.

The movement of air masses across North America from west to east is consistent with the global flow of wind over the continent. This is due to  general circulation of the Earth's atmosphere, which is driven by differences in temperature and pressure.

At the equator, warm air rises, creating low-pressure zone. As the air rises, it cools and releases moisture, thus creating tropical rainforests. This rising air then moves north and south, where it cools and sinks back to surface, thus creating high-pressure zones. The cool air then flows back toward equator, completing the circulation pattern known as Hadley cell.

In the mid-latitudes, the circulation pattern is more complex, with several cells interacting to create the prevailing westerlies that blow from west to east across North America.

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The final intensity of unpolarized light after passing through three polarizing filters is 12.5% of the original intensity.

This can be calculated using Malus' law, which states that the intensity of polarized light passing through a polarizing filter is proportional to the square of the cosine of the angle between the polarization axes of the filter and the incident light.

Therefore, the final intensity is 1/8 or 12.5% of the original intensity.

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Answer:

13.5 mA or 0.0135 A

Explanation:

1.

I=V/R

I=V/RI = 15 V/ 1,000 Ω

I=V/RI = 15 V/ 1,000 Ω

I = 0.015 A or 15 mA (milliamperes)

2.

I=V/R

I = 15 V/ 10,000 Ω

I = 0.0015 A or 1.5 mA (milliamperes)

3.

Therefore, the increase in current when the rheostat is adjusted to 1,000 Ω is:

Al 15 mA - 1.5 mA =

Al = 13.5 mA

So the increase in current is 13.5 mA or 0.0135 A

chatgpt

For a double-slit configuration where the slit separation is four times the slit width, the number of interference fringes that lie in the central peak of the diffraction pattern is 3.

This is because the number of bright fringes (interference fringes) that lie on either side of the central peak in a double-slit diffraction pattern is given by the equation:

nλ/d

where n is the order of the fringe, λ is the wavelength of the incident light, and d is the distance between the slits.

For the central peak, n is equal to zero, so the equation becomes:

0λ/d = 0

This means that there is no fringe at the center of the diffraction pattern.

However, there will be fringes on either side of the central peak, with the first order of bright fringe occurring at:

nλ/d = 1

where n = 1.

For a double-slit configuration where the slit separation is four times the slit width, the distance between the slits is 4w, where w is the width of each slit.

Therefore, the equation becomes:

nλ/4w = 1

nλ = 4w

This means that the first order of bright fringe will occur at a distance of 4w from the center of the diffraction pattern.

Similarly, the second order of bright fringe will occur at:

nλ/4w = 2n

λ = 8w

This means that the second order of bright fringe will occur at a distance of 8w from the center of the diffraction pattern.

Therefore, there will be a total of three interference fringes (bright fringes) in the central peak of the diffraction pattern.

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The launch speed of the box is approximately 6 m/s. To find the launch speed of the box, follow these steps:

1. Calculate the elastic potential energy (PE) stored in the spring when it's compressed by 20 cm (0.2 m):

[tex]PE = (1/2) * k * x^2[/tex]

[tex]PE = (1/2) * 270 N/m * (0.2 m)^2[/tex]

[tex]PE = 5.4 J (joules)[/tex]

2. Calculate the work done by friction (W) as the box slides across the floor:

W = friction force * distance

W = (coefficient of kinetic friction * normal force) * distance

Since the box is on a horizontal floor, the normal force equals the gravitational force on the box:

Fg = m * g

where m is the mass of the box and g is the acceleration due to gravity (approximately 9.81 m/s^2).

[tex]W = (0.23 * m * g) * distance[/tex]

3. Apply the work-energy theorem, which states that the work done on an object is equal to its change in kinetic energy (KE):

[tex]W = KE_final - KE_initial[/tex]

Since the box starts from rest, KE_initial = 0. So,

[tex]W = KE_final[/tex]

[tex]KE_final = 1/2 * m * v^2,[/tex] where v is the launch speed.

4. Equate the work done by friction to the elastic potential energy and solve for v:

[tex]5.4 J = 1/2 * (0.3 kg) * v^2[/tex]

[tex]v^2 = (5.4 J * 2) / 0.3 kg[/tex]

[tex]v^2 ≈ 36[/tex]

[tex]v ≈ 6 m/s[/tex]

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When released from a height of 1.60 m, a 1.50 kg block suspended from a light string hits the floor with a speed of 5.06 m/s.

To take care of this issue, we really want to utilize preservation of energy. The underlying possible energy of the block is changed over into active energy as it falls, dismissing any misfortunes because of erosion or air opposition.

To start with, we should track down the underlying expected energy of the block:

U_i = mgh

where

m = 1.50 kg (mass of the block)

g = 9.81 [tex]m/s^2[/tex] (speed increase because of gravity)

h = 1.60 m (range from which the block is delivered)

U_i = (1.50 kg)(9.81 [tex]m/s^2[/tex])(1.60 m) = 23.5 J

Then, we should find the last motor energy of the block not long before it strikes the floor:

K_f = (1/2)[tex]mv^2[/tex]

where

v = speed of the block not long before it strikes the floor

We can utilize protection of energy to relate the underlying likely energy to the last motor energy:

U_i = K_f

Subbing the qualities we viewed as above, we get:

23.5 J = (1/2)(1.50 kg)[tex]v^2[/tex]

Settling for v, we get:

v = sqrt[(2*23.5 J)/(1.50 kg)] = 5.06 m/s

Thusly, the speed of the block not long before it strikes the floor is 5.06 m/s.

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There are slightly less than 9,000 J of gravitational potential energy in the system.

The total energy in an isolated system is always conserved. This means that the total energy at the beginning of the process must equal the total energy at the end of the process. The total energy at the beginning is 18,000 J. We know that 6,000 J of this energy has been transformed into kinetic energy and 3,000 J has been transformed into elastic potential energy. So, the remaining energy must be gravitational potential energy.

We can calculate the remaining energy as follows:

Total energy = Kinetic energy + Elastic potential energy + Gravitational potential energy

18,000 J = 6,000 J + 3,000 J + Gravitational potential energy

Gravitational potential energy =  11,000.

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The rate at which electrons go past a certain point in an entire electrical circuit is known as the current. Cutting-edge is, at its core, fluidity.

Electric contemporary can be determined using the formula I=V/R for electric present day. This equation, which is derived from Ohm's Law, is also known as the "current equation." The variables "I," "V," and "R" stand for current, voltage, and resistance, respectively.

The strong current carried the couple away. A current of cool air was flowing in my face. A piece of graphite is used to transmit a powerful electric presence. Each event embodies a certain intellectual frontier.

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The magnitude of the induced emf in the coil while the magnetic field is changing is 15 volts.

We are given that the magnetic field changes from 0.50 T to 0.90 T in 2.0 s. The average rate of change of the magnetic field over this time interval is:

d(B)/dt = (0.90 T - 0.50 T) / 2.0 s = 0.20 T/s

Substituting the known values into the equation for magnetic flux and multiplying by the number of turns in the coil, we get:

Φ = NBA = (300)(0.50 T)(0.20 m²) = 30 Wb

Finally, substituting the magnetic flux and time into Faraday's law, we get:

emf = -dΦ/dt = -(ΔΦ/Δt) = -(30 Wb / 2.0 s) = -15 V

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Answer: C

Explanation:

The maximum data rate supported by this telephone line is approximately 43.84 kbps.

The maximum data rate of a channel can be calculated using the Shannon-Hartley theorem, which states that the channel capacity is equal to the channel bandwidth multiplied by the logarithm of the signal-to-noise ratio (SNR) plus 1, expressed in bits per second.

In this case, the bandwidth is 4 kHz, the signal amplitude is 10 V, and the noise amplitude is 5 mV. The SNR can be calculated by dividing the signal amplitude by the noise amplitude:

SNR = (signal amplitude) / (noise amplitude) = 10 V / 5 mV = 2000

Therefore, the maximum data rate is:

C = B log2(1 + SNR)

= 4 kHz * log2(1 + 2000)

= 4 kHz * 10.96

= 43.84 kbps

So the maximum data rate supported by this telephone line is approximately 43.84 kbps.

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Answer:

Vx = 80.0 / 5 = 16 m/s         horizontal speed

2.5 sec up, 2.5 sec down     speed of particle in vertical direction after falling for 2.5 sec

Vy = 2.5 * 9.8 = 24.5 m/s   vertical speed of particle

V = (Vx^2 + Vy^2)^1/2 = (16^2 + 24.5^2)^1/2 = 29.3 m/s

The initial speed of the projectile is 20.0 m/s

To solve for the initial speed of the projectile, we can use the fact that the projectile returns to its original height after 5.0 s of flight. This means that the time it takes for the projectile to reach its maximum height is 2.5 s (half of the total flight time).

Using the kinematic equation for vertical motion, we can find the initial vertical velocity of the projectile at launch:

Δy = v₀t + 0.5at²

where Δy = 0 (since the projectile returns to its original height), t = 2.5 s, a = -9.81 m/s² (acceleration due to gravity), and v₀ is the initial vertical velocity.

Solving for v₀, we get:

v₀ = -0.5at² / t

v₀ = -0.5(-9.81 m/s²)(2.5 s) = 12.26 m/s

Now that we know the initial vertical velocity, we can use the horizontal distance traveled (80.0 m) and the total flight time (5.0 s) to find the initial horizontal velocity:

v = d / t

v = 80.0 m / 5.0 s = 16.0 m/s

Therefore, the initial speed of the projectile is:

v₀i = √(v₀² + v²) = √(12.26² + 16.0²) ≈ 20.0 m/s

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A long solenoid that has 1 040 turns uniformly distributed over a length of 0.410 m produces a magnetic field of magnitude 1.00 10-4 T at its center.

To calculate the current required in the windings for this to occur, we will use the formula: B = μnI, where B = magnetic field, n = number of turns per unit length, I = current, and μ = permeability of free space.Substituting the given values into the formula, we have:B = μnI1.00 x 10^-4 T = 4π x 10^-7 T m/A x (1040/0.410) x IThe number of turns per unit length is n = 1040/0.410 = 2537.8 turns/m.I = (1.00 x 10^-4)/(4π x 10^-7 x 2537.8)I = 0.781 ATherefore, the current required in the windings for a long solenoid that has 1 040 turns uniformly distributed over a length of 0.410 m that produces a magnetic field of magnitude 1.00 x 10^-4 T at its center is 0.781 A.
To find the current required in the solenoid windings, you can use the formula for the magnetic field at the center of a solenoid: B = μ₀ * n * I, where B is the magnetic field, μ₀ is the permeability of free space (4π × 10⁻⁷ Tm/A), n is the number of turns per unit length, and I is the current.

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The displacement of the block from equilibrium when the elastic potential energy is equal to the kinetic energy is

x =a/sqrt(2).

When the elastic potential energy of the spring-block system is equal to the kinetic energy of the block, the displacement from equilibrium can be found using the conservation of energy principle. At this point, the total mechanical energy remains constant.

Let's denote the displacement from equilibrium as x. The elastic potential energy (PE) of the spring is given by (1/2)kx^2, and the kinetic energy (KE) of the block is given by (1/2)mv^2. Since PE = KE, we have:

(1/2)kx^2 = (1/2)mv^2

We also know that the maximum potential energy occurs when the block is pulled back a distance 'a', which is given by:

PE_max = (1/2)ka^2

Now, using the conservation of energy, we can write the total mechanical energy (E) as:

E = PE + KE = (1/2)kx^2 + (1/2)mv^2 = (1/2)ka^2

Substituting the expression for KE from the PE = KE equation, we get:
(1/2)kx^2 + (1/2)kx^2 = (1/2)ka^2
kx^2 = (1/2)ka^2

Now, solving for the displacement 'x', we find:

x^2 = (1/2)a^2
x = a / sqrt(2)

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The types of particles of sand that would make up the location would be Fine sand and silt. Option a

Sand is a granular material composed of finely divided rock and mineral particles with a particle size range of 0.063 to 2 mm. The properties of sand can vary depending on factors such as the source of the sand, the size and shape of the particles, and the environment in which it is found. However, some general properties of sand include:

Particle size: Sand particles are typically larger than silt and clay particles but smaller than gravel particles. They range in size from 0.063 to 2 mm in diameter.

Texture: Sand has a gritty texture and is often used in abrasive applications, such as sandpaper or sandblasting.

Color: The color of sand can vary depending on the composition of the particles. For example, sand made from quartz crystals is typically white or light-colored, while sand made from iron-rich minerals may be darker in color.

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If the speed of sound in air is 340 m/s and the gun produces a bang with a frequency of 1000 Hz,  the wavelength of the sound wave in the air is 0.34 m.

The formula for finding wavelength is given by λ = v/f

Where λ represents the wavelength, v represents the speed of sound in air, and f represents the frequency of the sound wave.

Using the given values, we have:

v = 340 m/s

f = 1000 Hz

λ = v/f

λ = 340/1000

λ = 0.34 m

Therefore, the wavelength of the sound wave in air is 0.34 m.

The distance between successive peaks or troughs of a wave is described by the word wavelength. It is usually denoted by the Greek letter lambda (λ). The wavelength of an electromagnetic wave, such as light, influences its colour or frequency.

The higher the frequency and energy of the wave, the shorter the wavelength. Wavelengths are measured in length units such metres (m), nanometers (nm), and angstroms (Å).

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True. A degausser is a device that creates a strong magnetic field to demagnetize magnetic storage media, such as hard drives, tapes, and floppy disks.

The purpose of a degausser is to erase data from the storage media by randomizing the magnetic orientation of the particles that represent the data, making it unreadable.

Degaussing is an important process in the field of data security, as it is often used to destroy sensitive information on magnetic media before disposal or reuse.

This is especially important in industries such as finance, healthcare, and government, where the risk of data theft or leakage is high. Degaussing is also a preferred method for erasing data from failed or obsolete magnetic media, as it can be performed quickly and effectively without damaging the storage device.

However, it is important to note that degaussing is not a foolproof method of data destruction, as some types of magnetic media may retain some residual data even after degaussing, making physical destruction or shredding a more reliable option for high-security data destruction.

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The work done by gravity on the box is 294 Joules (J) to two significant figures. In Physics, work is described as the energy transferred by a force, and it is calculated as the dot product of force and displacement.

Moreover, the work done by a force on an object is the product of the force magnitude and the distance covered in the direction of the force.  It is usually measured in Joules (J), and the unit is equal to the amount of work done when a force of 1 Newton (N) moves an object over a distance of 1 meter (m).

In this problem, the work wg done on the box by gravity can be computed as follows:wg = Fg * d * cos θWhere Fg is the force of gravity, d is the displacement, and θ is the angle between the direction of gravity and the displacement. Since the box moves vertically downwards, θ = 0, and cos θ = 1.

Therefore, wg = Fg * d.To find Fg, we can use Newton's second law, which states that the force is equal to the mass multiplied by the acceleration (F = ma).

Therefore, Fg = mg, where m is the mass of the box and g is the acceleration due to gravity, which is approximately 9.81 m/s².On the other hand, the displacement d is equal to the height h of the box above the ground. Thus, wg = Fg * h = mg * h = (10 kg) * (9.81 m/s²) * (3 m) = 294 J.

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