A solid cylinder with mass M. radius R, and rotational inertia 1/2MR² rolls without slipping down the inclined plane
shown above. The cylinder starts from rest at a height H. The inclined plane makes an angle with the horizontal.
Express all solutions in terms of M, R, H, theta, and g.

a. Determine the translational speed of the cylinder when it reaches the bottom of the inclined plane.

b. Show that the acceleration of the center of mass of the cylinder while it is rolling down the inclined plane is (2/3)g sin theta.

c. Determine the minimum coefficient of friction between the cylinder and the inclined plane that is required for the cylinder to roll without slipping.

There is a 34.9% difference between the observed wavelength and the predicted wavelength for the Balmer series line of hydrogen.

The Balmer series refers to the set of spectral lines in the visible part of the electromagnetic spectrum that are emitted by excited hydrogen atoms when they transition from higher energy levels to the second energy level. The formula for calculating the wavelength of the Balmer series lines is given by:

1/λ = [tex]R_H (1/2^2 - 1/n^2)[/tex]

where λ is the wavelength of the spectral line, R_H is the Rydberg constant for hydrogen [tex](1.0974 * 10^7 m^-1)[/tex], and n is an integer greater than 2 that represents the higher energy level from which the electron transitions.

For the Balmer series line with a wavelength of 656.5 nm, we can calculate the predicted wavelength using the formula above with n=3:

1/λ_predicted = [tex]R_H (1/2^2 - 1/3^2)[/tex]

[tex]= 1.0974 * 10^7 m^{-1} (1/4 - 1/9)[/tex]

= 4.862 x 10^-7 m[tex]= 4.862 * 10^{-7} m[/tex]

= 486.2 nm

The percentage difference between the predicted and observed wavelengths can be calculated using the formula:

% difference = |(observed wavelength - predicted wavelength) / predicted wavelength| x 100%

% difference = |(656.5 nm - 486.2 nm) / 486.2 nm| x 100%

= 34.9%

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The velocity of the jet relative to the air (its airspeed) is 156 m/s to the east.

We can solve this problem using vector addition. Let the velocity of the jet relative to the air be represented by vector A, and the velocity of the wind relative to the ground be represented by vector B.

The velocity of the jet relative to the ground is the vector sum of vectors A and B. We can find the magnitude and direction of vector A by using the Pythagorean theorem and trigonometry:

A² + B² = C²

where C is the magnitude of the velocity of the jet relative to the ground:

C = √(A² + B²) = √((155 m/s)² + (40.0 m/s)²) = 162 m/s

The direction of vector A can be found using the tangent function:

tan θ = B/A

where θ is the angle between vector A and the x-axis:

θ = tan⁻¹(B/A) = tan⁻¹((40.0 m/s)/(155 m/s)) = 14.1° north of east

Therefore, the velocity of the jet relative to the air (its airspeed) is:

A = C*cos(θ) = (162 m/s)*cos(14.1°) = 156 m/s to the east

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Total kinetic energy of a ostrich/child/bike is given by ptotal (= postrich + pchild/bike => 27.8 kg/m/s - 4.5 kg/m/s = 23.3 kg/m/s (in J). A body with mass m kg travelling at a speed of v m/s has momentum M = m*v kg*m/s.

Momentum can be thought of as a brain's "power" or the force that it can apply to another body while it is moving. For instance, a bowling ball with a heavy mass that is moving very slowly (low velocity) may have the same momentum as a baseball with a little mass that is thrown swiftly (high velocity).

More force is being applied to the truck than to the automobile. In motion, inertia is referred to as momentum. Momentum is calculated as the sum of an entity's mass and velocity. A tow van has far more momentum compared to a car driving at the exact same speed due to its increased weight.

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The altitude of the satellite is 2.24 × 10⁷ m.

Given, the centripetal acceleration of the satellite is a = 8.62 m/s²,

the tangential speed of the satellite is v = 7.65 × 10³ m/s,

the radius of the earth is R = 6.38 × 10⁶ m

We can find the altitude (h) of the satellite from the relation;

a = (v² / R) + (v² / h)

where, v is the tangential velocity, R is the radius of the Earth, h is the altitude of the satellite

Substitute the given values to calculate h;

a = (v² / R) + (v² / h)

8.62 = (7.65 × 10³)² / (6.38 × 10⁶) + (7.65 × 10³)² / h

h = (7.65 × 10³)² / (8.62) - (6.38 × 10⁶)h = 2.24 × 10⁷ m

Therefore, the altitude of the satellite is 2.24 × 10⁷ m.

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This occurs when airborne water vapour bumps up against the surface of a cold water bottle, causing the water vapour to condense into droplets.

The heat transported to or from a substance depends on three things, according to experiments: the change in temperature of the substance, its mass, and some physical characteristics associated to its phase.

Examples of heat engines that move energy from a cold place to a hot area include refrigerators and heat pumps.

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Kayla can determine which magnet has the most magnetic energy by performing an experiment using a magnetic pendulum.

What is a magnet?

A magnet is an object that has a magnetic field surrounding it. The magnetic field is what allows magnets to attract or repel other magnets. Magnets can be natural or man-made. A magnetic pendulum is a simple device that consists of a magnet hanging on a string.

When the magnet is brought near to another magnet, it will either be attracted or repelled. By measuring the amount of force required to move the magnet, Kayla can determine which magnet has the strongest magnetic field and therefore the most magnetic energy.

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AC current in your refrigerator is more likely to interfere with compass readings than DC current when you start your car.

Compass readings are interfered with by the magnetic fields that AC current and DC current generate. AC current generates a continuous magnetic field that oscillates, while DC current generates a steady magnetic field. Because of the oscillations, AC magnetic fields are much more likely to interfere with a compass than DC magnetic fields.

AC current's magnetic field is of greater intensity and flux density than DC current. The magnetic field generated by a refrigerator's AC motor is one of the main sources of electromagnetic interference that can disturb magnetic compass readings, particularly those in automobiles.

AC motors use a lot of energy, which produces magnetic fields that can interfere with the compass readings. The electrical system of a car uses DC, which generates a relatively steady magnetic field. When a car's engine is started, the battery is subjected to high levels of electrical noise, which can affect other electrical systems in the vehicle.

However, the interference produced is not strong enough to affect the compass reading when compared to the magnetic field produced by the AC motor in a refrigerator.

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Lobster traps are designed so that a lobster can easily get in but cannot easily get out. It is possible to create a diathermic wall that allows heat to flow through in one direction only. Diathermic walls are barriers that permit heat to flow through them in both directions.

Such walls are used in industrial applications to separate hot and cold regions of a system or for temperature control. However, it is possible to create a diathermic wall that allows heat to flow through in only one direction.

Heat moves from hot to cold regions in nature due to the second law of thermodynamics. However, if the diathermic wall is made up of alternate layers of high- and low-conductivity materials, heat will flow more quickly in one direction than in the other.

The side with the high-conductivity material will have a lower temperature than the side with the low-conductivity material. This temperature difference generates an electric current that opposes the flow of heat in the opposite direction, effectively blocking it.

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The magnitude of momentum of the ball after 3.333 sec is 10F/3 kg.m/sec. None of the options provided match this answer exactly.

What is Momentum?

Momentum is a physical property of an object that describes its motion. It is defined as the product of an object's mass and velocity, and it is a vector quantity, which means it has both magnitude and direction.

The magnitude of momentum of the ball after 3.333 sec can be calculated using the equation:

p = m * v

where p is momentum, m is mass, and v is velocity.

Given that the ball gains a velocity of 6m/s from the force and stops after 10 seconds, we can calculate the mass of the ball as:

v = F * t / m

6 = F * 10 / m

m = 10F / 6

m = 5F / 3

Now, we can calculate the momentum of the ball after 3.333 sec using the above equation:

p = m * v

p = (5F / 3) * (6 * 3.333 / 10)

p = (5F / 3) * 2

p = 10F / 3

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Answer:

a) A photon is a quantum of electromagnetic radiation. It is a particle-like entity that carries energy proportional to its frequency.

b)

i.

The energy of each photon can be calculated using the equation E = hf, where h is the Planck constant. The frequency of the radiation is not given in the question, so it cannot be calculated.

The maximum kinetic energy of each photoelectron can be calculated using the equation KEmax = hf - Φ, where Φ is the work function. Since the frequency is not given in the question, this cannot be calculated.

The current in the photocell is given as 1.2 x 10^-7 A.

To calculate the charge reaching the collector in 5.0 s, we can use the equation Q = It, where Q is the charge, I is the current, and t is the time. Thus, Q = (1.2 x 10^-7 A)(5.0 s) = 6.0 x 10^-7 C.

To calculate the number of photoelectrons reaching the collector in 5.0 s, we can use the equation Q = Ne, where N is the number of electrons and e is the elementary charge. Thus, N = Q/e = (6.0 x 10^-7 C)/(1.6 x 10^-19 C/electron) = 3.75 x 10^12 electrons.

ii.

The maximum kinetic energy of an ejected photoelectron can be calculated using the same equation as in part 1, with the values given in the question: KEmax = hf - Φ = (6.626 x 10^-34 J s)(7.0 x 10^14 Hz) - 3.5 x 10^-19 J = 4.62 x 10^-19 J, or 2.88 eV.

iii.

Doubling the intensity of the incident radiation while keeping the wavelength constant will increase the number of photons incident on the metal surface, and thus increase the number of photoelectrons emitted per second. This will result in an increase in the current in the photocell. However, it will not change the energy of each photon or the maximum kinetic energy of each photoelectron, since these values depend only on the frequency of the radiation.

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True. Thomas Edison was the first to create a portable motion picture camera and projection system in 1889.

The Kinetograph was the name of the first movie camera. It was the first camera that could capture moving images on a strip of film. George Eastman (later of Eastman Kodak Camera) created celluloid film in 1889, which was utilized in Edison's Kinetoscope and Kinetograph.

Edison developed the camera as well as its viewer and put on multiple demonstrations of his invention. The first still photographers, Joseph Nicephone Niepce and Louis Daguerre of France, were responsible for discovering the photographic principles upon which the camera was founded. His invention, known as the Kinetoscope, consisted of a camera, film, and projection system.

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We can find open circuit voltage by disconnecting one end of the circuit from the other end and short circuit current by connecting the two ends of the circuit together.

To find the open circuit voltage and short circuit current of an electrical circuit, the following steps should be taken:

In an electrical circuit, the open circuit voltage is the voltage between two points in a circuit when no current is flowing. The short circuit current is the current that flows when the two points in a circuit are connected, creating a short circuit. By measuring the open circuit voltage and short circuit current, we can understand how a circuit works.

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The natural length of the spring is 17 cm. Given that a 54J of work is needed to stretch a spring from 14 cm to 20 cm and 90J of work is needed to stretch it from 20 cm to 26 cm.

Let L be the natural length of the spring.

Total energy required to stretch the spring from natural length to 26 cm = 54 + 90 = 144 J

Total energy required to stretch the spring from natural length to 20 cm = (54 / 144) × 90 = 33.75 J

Total extension of the spring = (20 - L) cm

Now we need to equate the total extensions of the spring to find the natural length of the spring.(20 - L) + (26 - L) = 12cm46 - 2L = 12L = 17 cm

Therefore, the natural length of the spring is 17 cm.

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The uncertainty in the emitted wavelength is approximately: 0.013 nm.

The mean lifetime of an electronically excited state in a molecule is 5 ns. If this state emits at 500 nm, calculate the uncertainty in the emitted wavelength.

The uncertainty in the emitted wavelength can be calculated using the relation given below,Δλ = h/(4πmc)τ
Here, Δλ is the uncertainty in the emitted wavelength is Planck’s constant
m is the mass of an electron
c is the speed of light in vacuum
t is the lifetime of the excited state

Therefore, substituting the given values we have,Δλ = (6.626 × 10^-34)/(4π × 9.1 × 10^-31 × 3 × 10^8 × 5 × 10^-9)≈ 0.013 nm (approximately)

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The angular acceleration of a ladybug walks around a circular track that has a diameter of 3 m is 0.625 rad/s².The angular displacement is 60 rad.

Given that,The diameter of the circular track = 3m,Angular velocity of the ladybug = 5 rad/s.The time for which the ladybug moves = 12s. The formula for angular displacement is given by:

angular displacement = angular velocity × time (in seconds) = 5 rad/s × 12 s = 60 rad

So, the angular displacement is 60 rad.The formula for angular acceleration is given by:

angular acceleration = change in angular velocity / time taken (in seconds)

The initial angular velocity of the ladybug is zero, since it was at rest initially.The final angular velocity of the ladybug can be found using the formula:v = r × ωwhere,v = final linear velocity,r = radius of the circular track = 1.5m, ω = angular velocity= 5 rad/sv = 1.5 × 5 = 7.5 m/s

Therefore, the final angular velocity of the ladybug is 7.5 m/s.The change in angular velocity is given by:change in angular velocity = final angular velocity - initial angular velocity= 7.5 rad/s - 0 rad/s= 7.5 rad/s.The time taken for the ladybug to reach its final velocity is 12 seconds.Hence, the angular acceleration is given by:

angular acceleration = change in angular velocity / time taken (in seconds) = 7.5 rad/s / 12 s = 0.625 rad/s²

Therefore, the angular acceleration is 0.625 rad/s².

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Given that organic molecules need to react in order to produce life, this suggests we should search for worlds in the solar system that have:

Organic molecules are chemical compounds that include carbon and hydrogen atoms that are produced by living organisms. These molecules play a crucial role in the formation of life on Earth. Life on Earth began about 4 billion years ago with the formation of organic molecules in the oceans. In the search for life beyond Earth, scientists are searching for signs of organic molecules in other worlds in the solar system.

There are several criteria for finding life on other planets. The first criterion is that the planet must have either an atmosphere, or a surface or subsurface liquid media such as water, or both. This is because organic molecules need to react in order to produce life. Without an atmosphere or a liquid medium, the organic molecules will not react, and life cannot form.

The second criterion is that the planet must have organic molecules on its surface. Organic molecules can be produced by living organisms, or they can be produced by non-living processes such as meteorite impacts or volcanic activity. If organic molecules are found on the surface of a planet, it suggests that the planet has the potential to support life.

Therefore, we should search for worlds in the solar system that have either an atmosphere, or a surface or subsurface liquid media such as water, or both.

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According to Huygens’ wave theory, every point on the wavefront behaves as a source of secondary waves.

Christiaan Huygens, a Dutch mathematician and physicist, created the Huygens' wave theory. It's a hypothesis that light waves can be seen as tiny wavefronts that are each a spherical wave. According to Huygens, every point on a given wavefront acts as a secondary source of waves in Huygens' wave theory. Huygens' wave theory states that every point on a wavefront behaves as a source of secondary waves.

The Huygens' principle or Huygens-Fresnel principle states that light waves are generated from every point on a wavefront. It specifies that each point on a wavefront serves as a secondary source of spherical waves. This theory enables researchers to determine how light waves move and the laws that govern their propagation.

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False is the proper response. The magnitude of velocity is constant in a uniform circular motion. Therefore, the assertion is true.

How does the frequency or number of revolutions change when the washer's bulk rises?

The frequency increased with increasing bulk. The second formula can also be used to describe this relationship. The equation demonstrates the direct connection between acceleration and mass in the presence of constant load and diameter. The outcome is that an increase in mass causes an increase in velocity.

A uniformly moving item has a centripetal force that is constantly directed toward the center of the circle it is traveling in. When the applied circular path force is released, the item will travel on a single direction parallel to the curving route at a certain location.

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The required horizontal force to displace the position of a 28-kg chandelier is 33 N.

Here's how to calculate it:

Given: Mass of chandelier, m = 28 kg, Length of the wire, l = 4.0 m, Displacement of position, d = 0.12 m

When the chandelier is in a state of equilibrium, the tension T in the wire and the weight W of the chandelier must be equal.

The tension in the wire is equal to the force that is pulling the chandelier upwards. This force is acting at an angle of 90 degrees to the horizontal component of the tension in the wire.

Here, we can see that the chandelier is moving in a horizontal direction, so we need to calculate the horizontal component of the tension in the wire.

Taking moments about the point where the wire is attached to the ceiling: Anti-clockwise moments = clockwise moments

W * l = F * dF = (W * l)/d

Where W = mg (mass x gravity)

F = (28 kg x 9.8 m/s² x 4 m)/0.12 m= 33 N

The horizontal force required to displace the position of the chandelier 0.12 m to one side is 33 N.

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Answer:

PE = 1/2 K x^2        potential energy  

when x = A

PEt = 1/2 k A^2       total potential energy

If x = A / 2

PE 1/2= 1/2 k A^2 / 4    

PE1/2 / PEt = 1/4

Thus the PE at 1/2 the displacement is 1/4 the total

Since PE + KE = constant

3/4 the mass's energy will be KE at 1/2 the  amplitude

The electronic system used by the NYSE for directly transmitting orders to designated market makers is the Pillar system (option A).

The Pillar system is an electronic trading platform used by the New York Stock Exchange (NYSE) that enables direct transmission of orders from traders to designated market makers. The system is designed to improve speed, reliability, and efficiency of trading by automating the process of order routing and execution.

The Pillar system replaces the NYSE's previous trading platform, the NYSE Classic, and was introduced in 2017 as part of the exchange's efforts to modernize and streamline its operations. The system is intended to provide a more seamless and integrated trading experience for market participants.

Option A is the correct answer.

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The normal force acting on the object is equal to 145.8 N.

What is Normal Force?

Normal force is the force that a surface exerts on an object in contact with it, perpendicular to the surface. It is called the "normal" force because it is perpendicular ("normal" is a mathematical term meaning perpendicular) to the surface of contact. The normal force is equal in magnitude and opposite in direction to the component of the weight of the object that is perpendicular to the surface.

Assuming the inclined plane is frictionless, the only force acting on the object perpendicular to the plane is the normal force. The normal force (N) is equal and opposite to the force of gravity (mg) on the object, where m is the mass of the object and g is the acceleration due to gravity.

Using trigonometry, we can find the component of the force of gravity acting perpendicular to the inclined plane:

F_perpendicular = mg cos(theta)

where theta is the angle of inclination. In this case, theta = 25.0°, so we have:

F_perpendicular = (16.2 kg)(9.81 m/[tex]s^{2}[/tex]) cos(25.0°) ≈ 145.8 N

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According to Faraday's Law of Electromagnetic Induction, the magnitude of the induced EMF is directly proportional to the rate of change of magnetic flux with time, in this case the magnitude of the induced EMF in the wire is 14.05 V

The magnetic field through a loop of wire changes when it is exposed to a changing magnetic field. This induces an EMF in the wire.

The magnitude of the induced EMF is given by: ε = - N (dφ / dt)

where, N = number of turns of the wire in the loop

φ = magnetic flux

The rate of change of magnetic flux through the loop with time is given by:

[tex]\frac{d\phi}{dt}= \frac{d}{dt}(BAcos\theta) = AB (\frac{d}{dt}cos\theta)[/tex]

where,

B is the magnetic field,

A is the area of the loop, and

θ is the angle between the plane of the loop and the direction of the magnetic field.

In this case, a circular loop of wire with 53 turns and a radius of 15 cm is exposed to a perpendicular magnetic field of magnitude 0.45 T.

Therefore, the magnetic flux through the loop is given by:

φ = BA = πr²B= π (0.15 m)² (0.45 T) = 0.0318 Wb

When the magnetic field is reduced to zero in 0.12 s, the rate of change of magnetic flux with time is:

dφ/dt = -φ / t = (-0.0318 Wb) / (0.12 s) = -0.265 T/s

Therefore, the magnitude of the induced EMF in the wire is:ε = - N (dφ / dt) = - (53) (-0.265) V = 14.05 V

Therefore, the magnitude of the induced EMF in the wire is 14.05 V.

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A lens with a shorter focal length is better as a fire starter because it creates an image that is brighter. To burn a fire, we need a high light intensity. This means that the lens with a smaller focal length will be more effective.

Shorter focal length lenses create a bright, highly focused light beam which is ideal for a fire starter. A longer focal length lens produces a dimmer and more spread out light beam which would not be suitable for this purpose. When using a shorter focal length lens, the light is focused more narrowly and with more intensity, creating the necessary light intensity needed to start a fire.

Shorter focal length lenses also typically have larger apertures which allow more light to pass through the lens, resulting in a brighter image. Additionally, a shorter focal length lens also has a wider field of view which allows more light to enter the lens. This further contributes to the brightness of the image.

In conclusion, when all other things are equal, a lens with a shorter focal length is better as a fire starter because it creates a brighter image that has the necessary light intensity needed to start a fire. The wider field of view and larger aperture of a shorter focal length lens allows more light to pass through and create a brighter image.

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Explanation:

W = F * d      <====   ( Force * distance)

     500 N  * .7 m = 350 J

Wind was blowing in the exact same direction meets the sound traveling at 330 ms at a distance of 40 ms. Determine the distance the noise will travel in 15 seconds.

What on Earth generates wind?

Almost all of the winds on Earth have a direct link to the Sun. Air rises and falls as the Earth's surface is unevenly warmed by the Sun, creating high and low areas of air pressure. As pressure increases, the surrounding air fills in to replenish it as the pressure drops, creating wind.

What part does wind play in the development of landforms?

Such winds only occur at the lowest layers of the troposphere and have a localized extent. Since it is the primary geomorphic force responsible for sculpting different landforms, the wind system drives the evolution of different landforms on the earth's surface. Further information on the Erosion and Diagenetic effect of winds can be found here.

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The time it takes for the 10 kg mass to make one complete revolution on the table, given a tension of 51 N in the string, is 1.6 seconds. This value is calculated using the formula [tex]T = 2π√(r/g)[/tex] where r = 1.3 m and g = 9.8 m/s^2.

When a 10 kg mass is connected to a nail on a frictionless table by a massless string 1.3 m long, and the tension in the string is 51 N, the mass moves in a uniform circular motion. To find the time it takes for the mass to make one complete revolution, we use the formula [tex]T = 2π√(r/g)[/tex], where T is the time period, r is the radius of the circular path, and g is the acceleration due to gravity. Since the motion is on a table, the acceleration is zero and we can use the formula as is, with r = 1.3 m and [tex]g = 9.8 m/s^2[/tex]. Substituting these values, we get T = 1.6 seconds. Therefore, it takes 1.6 seconds for the mass to make one complete revolution on the table.

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A diffraction grating can be used, for example, to divide light into its many wavelengths or colours, enabling spectroscopic examination. We have the following by applying the grating spacing formula, d = 1/N, where N is the number of lines per unit length:

Normally, red light with a wavelength of 625 nm is impinge on an optical diffraction grating with a line density of 2 105 m

A diffraction grating often experiences an electromagnetic wave impinge on it. A second-order maximum is generated at a 30° angle to the grating's normal. There are 5000 lines per cm on the grating.

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The velocity of the target ball after the collision will be 1.32 / m².

Velocity of the target ball after the collision = (m1u1 + m2u2) / (m1 + m2)

Here, m1 = mass of the incoming softball = 0.220 kgm² = mass of the target ball = ?

u1 = initial velocity of the incoming softball = 4.0 m/su2 = initial velocity of the target ball = 0 m/sv1 = final velocity of the incoming softball = -2.0 m/s (because the incoming softball is bouncing backward)

v2 = final velocity of the target ball = ?

Substituting the given values in the above formula, we get:

v2 = (m1u1 + m2u2 - m1v1) / m2v2 = (0.220 x 4.0 + 0 x 0 - 0.220 x (-2.0)) / m2v2 = (0.880 + 0.440) / m2v2 = 1.32 / m²

Therefore, the velocity of the target ball after the collision is 1.32 / m².

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The wavelength of the incident photon is 2.48 x [tex]10^{-11}[/tex] m. The angle at which the photon is scattered is 0.24 radians. And the angle at which the electron recoils is 0.48 radians.

Calculating the Wavelength of the Incident Photon:

The wavelength of the incident photon can be calculated using the equation
λ = h/p, where h is Planck's constant and p is the momentum of the photon.

The momentum of the incident photon can be calculated using the equation p = E/c, where E is the energy of the incident photon and c is the speed of light.

Therefore, substituting the energy of the incident photon (80 keV) in the equation, we can calculate the momentum of the incident photon:

p = 80 keV/ (3 x [tex]10^8[/tex] m/s) = 2.67 x [tex]10^{-24}[/tex] kg.m/s

Therefore, the wavelength of the incident photon can be calculated using the equation:
λ = h/p
= 6.63 x [tex]10^{-34}[/tex] J.s/ (2.67 x [tex]10^{-24}[/tex] kg.m/s )
= 2.48 x [tex]10^{-11}[/tex] m

Calculating the Angle at which the Photon is Scattered:

The angle at which the photon is scattered can be calculated using the Compton scattering equation, which is
Δθ = (h/mc) (1 - cos θ),
where Δθ is the change in the angle of the photon's trajectory, h is Planck's constant, m is the mass of the electron, and θ is the angle at which the photon is scattered.

The mass of the electron can be calculated using the equation m = [tex]E/c^2[/tex], where E is the energy of the electron and c is the speed of light.

Therefore, substituting the energy of the electron (25 keV) in the equation, we can calculate the mass of the electron:
m = 25 keV/ (3 x [tex]10^8[/tex] [tex]m/s)^2[/tex]
= 8.33 x [tex]10^{-36}[/tex] kg

Therefore, the angle at which the photon is scattered can be calculated using the Compton scattering equation:
Δθ = (h/mc) (1 - cos θ)
= (6.63 x [tex]10^{-34}[/tex] J.s/ (8.33 x [tex]10^{-36}[/tex] kg) (1 - cos θ)
= 0.24 radians.

Calculating the Angle at which the Electron Recoils:

The angle at which the electron recoils can be calculated using the equation θ = 2Δθ,
where Δθ is the change in the angle of the photon's trajectory.

Therefore, substituting the value of Δθ (0.24 radians) in the equation, we can calculate the angle at which the electron recoils:
θ = 2Δθ
= 2 x 0.24
= 0.48 radians.

Thus, the wavelength of the incident photon is 2.48 x [tex]10^{-11}[/tex] m, the angle at which the photon is scattered is 0.24 radians, and the angle at which the electron recoils is 0.48 radians.

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