if an object rolls down a ramp, how does the velocity of that object at the bottom of the ramp compare with the height of the object at the top?

Answer:

13. a) In Einstein's photoelectric equation, hf represents the energy of a single photon of the electromagnetic radiation, and mvmax² represents the maximum kinetic energy of the emitted photoelectrons.

b) i. To calculate the threshold frequency, we can use the equation c = fλ, where c is the speed of light, f is the frequency of the electromagnetic radiation, and λ is the wavelength:

c = fλ

f = c/λ

f = (3.00 x 10^8 m/s)/(6.5 x 10^-7 m)

f = 4.62 x 10^14 Hz

Therefore, the threshold frequency is 4.62 x 10^14 Hz.

ii. We can use the equation hf = Φ + KEmax, where hf is the energy of a single photon, Φ is the work function energy of the metal, and KEmax is the maximum kinetic energy of the emitted photoelectrons. We know that the wavelength of the incident electromagnetic radiation is 6.5 x 10^-7 m, which corresponds to a frequency of f = 4.62 x 10^14 Hz (as calculated in part i). We also know that this wavelength is the maximum for which photoelectrons are released, which means that the energy of the photons is equal to the work function energy:

hf = Φ

Substituting the values for h and f, we get:

(6.63 x 10^-34 J s)(4.62 x 10^14 Hz) = Φ

Φ = 1.93 x 10^-19 J

Converting this to electronvolts (eV), we get:

Φ = (1.93 x 10^-19 J)/(1.60 x 10^-19 J/eV)

Φ = 1.21 eV

Therefore, the work function energy of the metal is 1.9 eV.

c) If the intensity of the incident light is doubled, the rate of release of photoelectrons will also double. This is because the intensity of light is directly proportional to the number of photons incident on the metal surface per unit time. Each photon can cause the emission of one photoelectron, so doubling the number of photons will double the number of emitted photoelectrons per unit time. However, the kinetic energy of the emitted photoelectrons will not change, since this is determined only by the frequency (and therefore the energy) of the incident photons, and not by their intensity.

The statement that  best describes the result of moving the charge to  the point marked X is: B. Its electric potential energy increases because the electric field increases.

Moving the charge to the point marked X will change its electric potential energy because the electric field at that point is different from the electric field at its initial position.

At the initial position of the charge, the electric potential energy is determined by the electric potential at that point and the charge of the object. When the charge is moved to point X, the electric potential at that point changes, which means that the electric potential energy of the charge also changes. This is because the electric potential at a point is directly proportional to the electric field at that point.

Therefore, since the electric field is different at point X than at the initial position, the electric potential energy of the charge increases as it moves to point X.

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When the magnitude of the electric field in an EM wave is doubled, the intensity of the wave increases by a factor of 4. The correct option is c. It quadruples.

The intensity (I) of an electromagnetic wave is given by:

I = (1/2)ε0cE^2

where ε0 is the electric constant, c is the speed of light, and E is the magnitude of the electric field.

If the magnitude of the electric field in an electromagnetic wave is doubled, the intensity of the wave will increase by a factor of four (4), because:

I' = (1/2)ε0c(2E)^2 = 4(1/2)ε0cE^2 = 4I

The correct answer is (c) It quadruples.

Electromagnetic waves are waves that are produced by oscillating electric and magnetic fields. An electromagnetic wave is composed of electric and magnetic fields that oscillate perpendicularly to each other and to the direction of wave propagation. Light, microwaves, X-rays, and radio waves are all examples of electromagnetic waves.

The power transferred per unit area by an electromagnetic wave is known as the intensity of the wave. The magnitude of the electric field in an EM wave is related to its intensity. When the magnitude of the electric field in an EM wave is doubled, the intensity of the wave quadruples.

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Currents can be created by magnetic fields. A current is capable of creating a magnetic field.

Magnetic fields are constantly shifting, pushing and pulling electrons. Metals like copper and aluminium have slackly held electrons. As a magnet is moved around a wire or a coil of wire, the electrons in the wire are pushed, creating an electrical current.

Sound energy can be made up of both kinetic and potential energy. A musical instrument is one possible illustration. When the instrument is performed, sound waves are produced that have kinetic energy. Nevertheless, potential energy is all that is present when that same musical instrument is at rest.

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The turning point's y-value is indeed the largest. As a consequence, we must discover the greatest quadratic function indicating that perhaps the ball would achieve a height limit of 72.5 feet. Which indicates:

[tex]x = 110.90[/tex] or [tex]x = -0.90[/tex]

Given that we're working with time,

[tex]x = 110.90[/tex]

We have 110.9 feet to the nearest decimal place.

Why is it referred to as a quadratic function?

A quadratic issue is a type of challenge in mathematics that deals with something like a variable multiplication by itself, which is defined as squaring. This language stems from the fact that the area of a square is equal to its line segment multiplied by itself. The term "quadratic" is derived from quadratum, which is the Latin word meaning square.

Describe the three different kinds of quadratic functions?

Quadratics are typically utilized in three ways:

1)Standard Form: y = an x 2 + b x + c y=ax2+bx+c y=ax2+bx+c y=ax2+bx+c.

2)Factored Form: y = a (x r 1) (x r 2) y=a(x-r 1)(x-r 2) y=a(xr1)(xr2) y=a(xr1)(xr2).

3)Vertex Form: y = a (x h) 2 + k y=a(x-h)2+k y=a(xh)2+k.

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The frictional force required to keep the car on the circular track will increase by a factor of four when the speed of the car is doubled.

The centripetal force required to keep a car moving in a circular path is given by the formula F = mv²/r, where m is the mass of the car, v is its speed, and r is the radius of the circular path. In this case, the force of friction provides the necessary centripetal force to keep the car on the track.

When the speed of the car is doubled, the centripetal force required to keep it on the circular path increases by a factor of four, because the velocity appears squared in the formula for centripetal force. Therefore, the frictional force needed to keep the car on the road must also increase by a factor of four.

This means that if the original frictional force was F, then the new frictional force needed will be 4F.

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Explanation:

To find the net (total) force on the ball, we need to add the two forces together. Since the two players are kicking the ball from opposite sides, we need to subtract the force of the player kicking in the opposite direction.

Therefore, the net force on the ball is:

63 N (force of Blue #5) - 50 N (force of Red #3) = 13 N

The net force on the ball is 13 Newtons in the direction of Blue #5's kick.

The radial acceleration of a point on the second hand of a large clock is 0.14 cm/s². Using the formula for radial acceleration, the distance of the point from the axis of rotation is approximately 11.3 cm.

The radial acceleration of a point on a rotating object is the acceleration that points towards the center of rotation. This acceleration arises due to the object's circular motion and is given by the formula a = v²/r, where a is the radial acceleration, v is the tangential velocity of the object, and r is the radius of the circular path. In this case, we know that the radial acceleration of the point on the second hand of the clock is 0.14 cm/s². Since the second hand completes one full revolution in 60 seconds, we can find its tangential velocity using the formula v = 2πr/T, where T is the time taken for one revolution. Substituting T = 60 seconds, we get v = 0.1047 cm/s. We can now use the formula for radial acceleration to find the radius of the circular path followed by the point on the second hand. Rearranging the formula, we get r = v²/a, which gives us a value of approximately 11.3 cm for the distance of the point from the axis of rotation.

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Answer:

The refractive index of a material is a measure of how much the speed of light is reduced when it passes through that material.

The formula for calculating the refractive index of a material is:

n = c/v

where n is the refractive index, c is the speed of light in a vacuum (approximately 3 x 10^8 m/s), and v is the speed of light in the material.

When light travels from one material to another and refracts at the boundary, the angle of refraction and the refractive index of the first material and the refractive index of the second material determine the way in which the light bends.

If light passes at an angle into a material, it will bend towards the normal (the perpendicular line) if the refractive index of the second material is greater than the refractive index of the first material. If the refractive index of the second material is less than the refractive index of the first material, the light will bend away from the normal.

The below diagram shows the path of light as it passes from air into a denser material (in this case, glass). The angle of refraction is determined by the refractive indices of the two materials and the angle of incidence.

The de Broglie wavelength of a particle is given by the equation:

λ = h/p

where λ is the de Broglie wavelength, h is Planck's constant (approximately 6.626 x 10^-34 J s), and p is the momentum of the particle.

To calculate the momentum of a particle, use the equation:

p = mv

where p is the momentum, m is the mass of the particle, and v is its velocity.

To calculate the associated de Broglie wavelength of electrons in an electron beam accelerated through a potential difference (pd) of 4000 V, use the equation:

λ = h/√(2meV)

where λ is the de Broglie wavelength, h is Planck's constant, me is the mass of an electron (approximately 9.11 x 10^-31 kg), and V is the potential difference.

To calculate the energy of an alpha particle with a de Broglie wavelength of 5.7 x 10^-15 m, use the equation:

E = hc/λ

where E is the energy of the particle, h is Planck's constant, c is the speed of light, and λ is the de Broglie wavelength. The energy can then be converted to MeV (million electron volts) by dividing by 1.6 x 10^-13 J/MeV.

(Please could you kindly mark my answer as brainliest you could also follow me so that you could easily reach out to me for any other questions)

Answer:

no

Explanation:

because when he jumps into the swimming pool he will not be able to swim comfortably

In a uniform field, a beam has no magnetic poles and therefore experiences a force equal to the product of its length and the field intensity. whereas bar magnet is influenced by the interaction between its magnetic poles and the field intensity.

When placed in a uniform field, the bar magnet experiences a torque, which causes it to align itself with the field direction. In contrast, a beam placed in a uniform field experiences a uniform force, which acts parallel to the field direction and perpendicular to the beam length. This force tends to cause the beam to move in the direction of the field intensity. The magnitude of the force on the beam is proportional to the length and field intensity, as well as the product of its magnetic permeability and the field intensity.

The force on the beam also tends to cause it to rotate about its center, in the direction of the field intensity. This rotation will result in the beam becoming oriented along the field direction, but it will not cause the beam to align itself with the field direction as with a bar magnet. Instead, the beam will experience a net force, which tends to move it in the direction of the field intensity.

In conclusion, the behavior of a beam in a uniform magnetic field differs from the behavior of a bar magnet in several ways. A beam placed in a uniform field experiences a uniform force, which acts parallel to the field direction and perpendicular to the beam length. This force tends to cause the beam to move in the direction of the field intensity and rotate about its center, in the direction of the field intensity.

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Select a white dwarf or other star that is known to be relativity close and steady in its brightness as your reference point. When Mars is on separate sides of the sun, see the target star twice, six months apart.

The parallax angle can be used to calculate distance. It is occupied at the two sites on Earth that are separated by b by the far-off celestial object.

When measuring the distance between the earth and other planets and stars using the parallax method, we estimate the position of a first from one position, then from another. Calculating the distance from a star or planet involves measuring the amount of shift that occurs in its location.

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If the winner started the acceleration first, he will be 31.24 m ahead of the loser when the loser finishes.

Let the winner's initial position be at x = 0. Assume that the loser is a distance d away from the winner's initial position. Therefore, the loser's initial position is at x = -d.The winner starts to accelerate when the other racer is 6.5 m ahead of him. When the winner reaches a speed of 12.2 m/s, the other racer has traveled a distance of 6.5 m.

The time it takes the winner to catch up to the other racer can be found using the equation:

x = vt + 1/2at^2

where x = 6.5 m, v = 12.2 m/s, and a = 0.

The time t is: 6.5 m = 12.2 m/s × t

Thus, t = 0.533 s.

From that time on, the winner continues to cycle at a constant speed of 12.2 m/s until the finish line. The distance the winner travels between catching up to the other racer and crossing the finish line is: Distance traveled by the winner = 12.2 m/s × (18.3 s – 0.533 s) = 224.43 m. Distance between the winner and the other racer after crossing the finish line is: 12.2 m/s × (18.3 s – 15.0 s) = 40.26 m.

Hence, the distance between the loser and the finish line is (65.0 m – 40.26 m) = 24.74 m. Distance the winner will travel before the loser finishes: 24.74 m + 6.5 m = 31.24 m.

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The direction of the force of static friction on an incline is perpendicular to the surface, while on a flat surface, it is parallel to the surface. This is because the incline introduces a component of the gravitational force that acts perpendicular to the surface.

On a flat surface, the force of static friction is parallel to the surface and opposite in direction to the applied force. However, on an incline, the component of gravitational force perpendicular to the surface creates a normal force that is also perpendicular to the surface. The force of static friction acts perpendicular to both the normal force and the inclined surface since it's always perpendicular to the normal force. This change in direction occurs because the force of static friction is a reactionary force that opposes the motion, and its direction depends on the forces acting on the object. Therefore, the direction of the force of static friction changes based on the orientation of the surface on which the object is placed.

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The anthracite coal price per MMBtu is $3.00/MMBtu. Therefore, the correct option is A.

The heat content of anthracite coal is 15,000 BTU/pound. The question requires the conversion of an anthracite coal price of $90/ton to $/MMBtu. Let us use the given data to solve the problem. 1 ton equals 2000 pounds (lb). Hence,

2000 lb of anthracite coal has a heat content of 2000 lb x 15,000 BTU/lb = 30,000,000 BTU

Thus, the price per MMBtu can be calculated by the given formula;

Price per MMBtu = Price per ton / (BTUs per ton / MMBTUs per ton)

Price per MMBtu = $90 / (30,000,000 / 1,000,000)

Price per MMBtu = $90 / 30

Price per MMBtu = $3.00/MMBtu

Thus, the price per MMBtu of anthracite coal is $3.00/MMBtu. Therefore, the correct answer is option A: $3.00/MMBtu.

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Answer: maybe read your book

Explanation:

When you place a thumbtack 54.0 cm in front of a lens, the resulting image is real, inverted, and the same size as the thumbtack, then the lens in this case is a converging lens.

Converging lenses are thick in the middle and thin at the edges. They are convex in shape, which means they bulge outwards. Converging lenses can converge light rays to a point on the other side of the lens. They are also known as convex lenses, and they have a positive focal length.

The image produced by a converging lens can be real or virtual depending on the position of the object relative to the lens. The image of the object is real when the object is placed beyond the focal point of the lens, as in this situation.

Therefore, when you place a thumbtack in front of a lens, the resulting image is real, inverted, and the same size as the thumbtack. that means the lens is a converging lens.

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(a) The total energy is 0.098 J.

(b)The kinetic and potential energies as a function of time is, K = 1/2 m (0.808 m/s)^2 sin^2 (8.08t) and U = 1/2 (19.6 N/m) (0.100 m)^2 cos^2 (8.08t) respectively.

(c) The velocity when the mass is 0. 050 m from equilibrium is (0.808 m/s) sin (8.08t).

(d) The kinetic and potential energies at half amplitude is, K = 0 and U = 0.098 J.

The total energy of the simple harmonic oscillator can be found using the formula E = 1/2 k A^2, where k is the spring constant and A is the amplitude, E = 1/2 (19.6 N/m) (0.100 m)^2 = 0.098 J

The kinetic energy (K) and potential energy (U) can be expressed in terms of the displacement (x) and velocity (v) as follows:

K = 1/2 m v^2 = 1/2 m (0.808 m/s)^2 sin^2 (8.08t)

U = 1/2 k x^2 = 1/2 (19.6 N/m) (0.100 m)^2 cos^2 (8.08t)

To find the velocity when the mass is 0.050 m from the equilibrium, we substitute x = 0.050 m into the expression for v,

v = (0.808 m/s) sin (8.08t) = (0.808 m/s) sin (8.08t) when x = 0.050 m

At half amplitude (x = A/2 = 0.050 m), the kinetic energy is zero and the potential energy is equal to the total energy,

K = 0

U = E = 0.098 J

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The galvanometer briefly swung to one side. The galvanometer is in the other way. There is no galvanometer deflection. Electromagnetic induction is the relevant phenomenon. The galvanometer is in the opposite direction from that in the previous case. There is no galvanometer deflection.

The observations that will occur for each choice when a coil of insulated copper wire is coupled to a galvanometer are as follows:

(I) Electromagnetic induction will cause the coil to create an electric current if a bar magnet is put into it.

(ii) If a bar magnet is removed from the inside, electromagnetic induction will again induce current in the copper wire, but this time the direction of the current in the galvanometer will be reversed.

(iii) If a bar magnet is kept stationary inside the coil, no current is produced, and as a result, the galvanometer does not deflect.

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The ammeter and voltmeter should be read simultaneously to determine the resistance of a circuit component because the resistance depends on the current passing through the component and the voltage drop across it. By measuring both the current and voltage, Ohm's law (V=IR) can be applied to calculate the resistance of the component.

The resistance of a circuit component represents how much it impedes the flow of current through it. According to Ohm's law, the voltage drop across a component is directly proportional to the current flowing through it, and the constant of proportionality is the resistance of the component. Therefore, to determine the resistance of a component, we need to know both the current passing through it and the voltage drop across it.

An ammeter is used to measure the current flowing through a circuit, while a voltmeter is used to measure the voltage difference between two points in the circuit. By reading both instruments simultaneously, we can use Ohm's law to calculate the resistance of the component being measured.

It is important to note that the readings must be taken simultaneously because the current and voltage can change over time, and any delay between taking the readings can result in inaccurate measurements. Therefore, it is necessary to read the ammeter and voltmeter at the same time to obtain an accurate measurement of the resistance of the component.

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The speed required to push the box is approximately 11.27 m/s.

Given the angle of inclination of the slope, θ = 18°. The distance covered is, d = 15 meters.

The component of gravity parallel to the slope is, g|| = g.sinθ

The force required to push the box up the slope is, F = m.g, The acceleration due to gravity is, g = 9.81 m/s².

The weight of the box is, m.g. The component of gravity parallel to the slope is, g|| = g.sinθ.

The force required to push the box up the slope is, F = m.g||

The force required to push the box up the slope is,F = m.g.sinθ.

The frictionless surface has no frictional force acting upon the object moving upon it. Therefore, no work is done by friction on the object. Hence, the energy of the object in the form of kinetic energy is conserved. This is as given below:

K.E. initial + work done = K.E. finfinalitial kinetic energy is zero. This is because the box is initially at rest. The final kinetic energy is K. This is because we need to push the box up the slope with the required force. The work done is equal to the force exerted multiplied by the distance moved in the direction of the force.

Hence,W = F.dThe final equation becomes,0 + F.d = ½.m.K²The final speed required is,K = √(2.F.d/m)Substituting the values in the above equation, we get the required final speed,K = √(2.m.g.sinθ.d/m)K = √(2.g.sinθ.d)Putting the values of d, g, and θ in the equation, we get,K = √(2.9.81.sin18°.15)≈ 11.27 m/s.

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Answer:

Explanation:

An earthquake, with its sudden and cataclysmic rupturing of the earth's crust, is a sublime exhibition of the extraordinary might of nature. This geological upheaval arises from the movements of tectonic plates - vast and ponderous slabs of rock comprising the earth's outermost layer. These plates glide past each other, collide, or diverge, accumulating seismic energy that they discharge as seismic waves, shaking the earth to its core.

The factors that underlie an earthquake are complex and multifarious, spanning the entire spectrum of geological events, from volcanic activity to anthropogenic interventions such as drilling and mining. Nevertheless, the dominant causal factor is the intricate interplay of tectonic plates, ceaselessly engaged in a dynamic dance of motion, friction, and release, culminating in an earthquake's fearsome display of raw power.

Despite their potential for devastation, comprehending the causes of earthquakes can inform and enhance our preparedness for these events, and equip us with the knowledge to mitigate their impact on human society. It may also allow us to deepen our appreciation of the natural world's enigmatic processes, and our place within it, engendering a richer understanding of our planet and its precarious balance.

Answer:

It would be 2850 kg m/s

Explanation:

The wavelength of a wave is the distance between two consecutive points on the wave that are in phase.

The wavelength is the distance between two consecutive nodes or two consecutive antinodes.

The first harmonious wavelength on a rope is given by the equation

λ = 2L/ n

where λ is the wavelength, L is the length of the rope, and n is the harmonious number. For the first harmonious, n = 1.

In this case, the length of the rope is L = 4m. Substituting into the equation over, we get

λ = 2( 4m)/ 1

λ = 8m

thus, the first harmonious wavelength on the rope is 8 measures.

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The amount of time the baseball was in air for at a momentum of 0.85kgm/s is 0.399s

Momentum is the product of its mass and velocity, or the vector sum of the products of its masses and velocities. It can be calculated as follows:

Momentum = mass (m) × velocity (v)

However, the momentum of an object can be estimated using the following;

ΔM = F × ΔT

Where;

F = mass × acceleration

F = 0.213kg × 10m/s² = 2.13N

0.85 = 2.13 × t

t = 0.399s

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Answer:

Approximately [tex]15.5\; {\rm N}[/tex], assuming that [tex]g = 9.81\; {\rm N \cdot kg^{-1}}[/tex].

Explanation:

To find the tension in the rope on the right side of the pulley, apply the following steps:

The net force on the block is:

[tex]F_{\text{net}} = m_{\text{b}} \, a[/tex], where

At the same time, the net force on the block can also be expressed as:

[tex]\begin{aligned}F_{\text{net}} &= T_{\text{left}} - (\text{weight}) \\ &= T_{\text{left}} - m_{\text{b}}\, g \end{aligned}[/tex], where

Rearrange and solve for [tex]T_{\text{left}}[/tex]:

[tex]T_{\text{left}} - m_{\text{b}}\, g = F_{\text{net}} = m_{\text{b}}\, a[/tex].

[tex]\begin{aligned}T_{\text{left}} &= m_{\text{b}}\, a + m_{\text{b}}\, g \\ &= m_{\text{b}}\, (a + g) \\ &= 1.3\, (1.2 + 9.81)\; {\rm N} \\ &= 14.313\; {\rm N}\end{aligned}[/tex].

Let [tex]r[/tex] denote the radius of the pulley. It is given that the diameter of the pulley is [tex]50\; {\rm cm}[/tex]. In standard units, the radius of the pulley would be [tex]r = 25\; {\rm cm} = 0.25\; {\rm m}[/tex].

On the left side of the pulley, tension in the rope exerts a torque of [tex]\tau_{\text{left}} = T_{\text{left}}\, r[/tex] on the pulley:

[tex]\begin{aligned}\tau_{\text{left}} &= T_{\text{left}}\, r \\ &= (14.313)\, (0.25)\; {\rm N\cdot m} \\ &= 3.57825\; {\rm N\cdot m} \end{aligned}[/tex].

Under the assumptions, the moment of inertia [tex]I[/tex] of this cylindrical pulley would be:

[tex]\begin{aligned} I &= \frac{1}{2}\, m\, r^{2} \end{aligned}[/tex], where

[tex]\begin{aligned} I &= \frac{1}{2}\, m\, r^{2} \\ &= \frac{1}{2}\, (2.0)\, (0.25)^{2}\; {\rm kg \cdot m^{2}} \\ &= 0.0625\; {\rm kg\cdot m^{2}} \end{aligned}[/tex].

Since the rope doesn't slip on the pulley, linear acceleration of the pulley would be equal to that of the rope, [tex]a = 1.2\; {\rm m\cdot s^{-2}}[/tex]. Divide this linear acceleration by the radius of the pulley to find the angular acceleration [tex]\alpha[/tex] of the pulley:

[tex]\begin{aligned}\alpha &= \frac{a}{r} \\ &= \frac{1.2}{0.25}\; {\rm s^{-2}} \\ &= 4.8\; {\rm s^{-2}}\end{aligned}[/tex].

Multiply angular acceleration by the moment of inertia to find the net torque [tex]\tau_{\text{net}}[/tex] on the pulley cylinder:

[tex]\begin{aligned}\tau_{\text{net}} &= I\, \alpha \\ &= (0.0625)\, (4.8)\; {\rm kg \cdot m^{2}\cdot s^{-2}}\\ &= 0.3\; {\rm kg \cdot m^{2} \cdot s^{-2}} \end{aligned}[/tex].

Note that the net torque of the pulley [tex]\tau_{\text{net}}[/tex] is in the same direction as [tex]\tau_{\text{right}}[/tex], but the opposite of [tex]\tau_{\text{left}}[/tex]. Hence:

[tex]\begin{aligned}\tau_{\text{right}} &= \tau_{\text{net}} + \tau_{\text{left}} \\ &= 0.3\; {\rm N\cdot m} + 3.57825\; {\rm N\cdot m} \\ &= 3.87825\; {\rm N\cdot m}\end{aligned}[/tex].

Divide the torque on the right [tex]\tau_{\text{right}}[/tex] by radius [tex]r[/tex] to find the tension in the string on the right [tex]T_{\text{right}}[/tex]:

[tex]\begin{aligned}T_{\text{right}} &= \frac{\tau_{\text{right}}}{r} \\ &= \frac{3.87825}{0.25}\; {\rm N} \\ &= 15.513\; {\rm N}\end{aligned}[/tex].

Living a physically active lifestyle can improve academic performance by increasing energy and focus, improving mood and mental health, enhancing memory and cognitive function, improving sleep quality, and reducing absenteeism.

Living a physically active lifestyle can have a positive impact on your academic performance in several ways:

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The magnitude of the ball's acceleration when it leaves the gun, as a multiple of g, if it is shot straight up is -1g.

When the ball is shot straight up, its initial velocity is zero. Therefore, its final velocity is zero when it reaches the highest point in its trajectory. Using the kinematic equation,

vf^2 = vi^2 + 2ad

where, vf, vi are final and initial velocity, a is acceleration, and d is displacement

At the highest point in the ball's trajectory, its final velocity is zero, and its initial velocity is also zero. Therefore, the equation becomes:

0 = 0 + 2ad

which gives us the displacement of the ball as it moves upward from the gun.

Using this equation to find the time it takes for the ball to reach its highest point, we get,

t = √(2d/a)

At the highest point in the ball's trajectory, its velocity is zero, and its acceleration is equal to the acceleration due to gravity, which is -g. Therefore, using the kinematic equation to find the displacement of the ball:

d = vit + 1/2at^2

Substituting for vi, t and a,

d = -1/2g(√(2d/a))^2d = -d/2

Therefore, the displacement of the ball is negative, which means that the ball is below its initial position.

Therefore, the magnitude of the ball's acceleration is -1g.

Know more about acceleration here:

https://brainly.com/question/27898978

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