The plots of acceleration, velocity, and position as a function of time for an object on a slope indicate a constant negative acceleration, a linearly decreasing velocity, and a quadratic position-time relationship. These plots demonstrate the interrelated nature of these quantities and provide insights into the object's motion on the slope.
The motion of an object on a slope with the X-axis perpendicular to the ground and pointing upwards can be described by the plots of acceleration, velocity, and position as a function of time. The acceleration is constant and given by the gravitational acceleration, g, in the opposite direction to the positive X-axis. The velocity of the object will change linearly with time, and the position will exhibit a quadratic relationship with time. These plots are interrelated and can be understood by considering the relationships between acceleration, velocity, and position in the context of the object's motion on the slope.
(1) Acceleration: The acceleration of the object on the slope is constant and equal to the gravitational acceleration, g. Since the X-axis is perpendicular to the ground and pointing upwards, the acceleration will be -g (negative sign indicating it acts in the opposite direction to the positive X-axis). Thus, the plot of acceleration versus time will be a horizontal line at -g.
(2) Velocity: The velocity of the object will change linearly with time under constant acceleration. As the acceleration is constant, the velocity-time graph will be a straight line. Since the acceleration is -g, the velocity will decrease linearly over time, indicating deceleration. The slope of the velocity-time graph represents the rate of change of velocity, which is equal to the acceleration (-g) in this case.
(3) Position: The position of the object on the slope will exhibit a quadratic relationship with time. This can be understood by considering the equation for the position of an object under constant acceleration: x = x0 + v0t + (1/2)at^2, where x0 is the initial position, v0 is the initial velocity, a is the acceleration, and t is the time. Since the initial position and velocity are typically taken as zero, the position-time graph will be a quadratic curve, representing the displacement of the object on the slope.
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Two long, straight wires are perpendicular to the plane of the paper as shown in the drawing.
The wires carry currents of I = 3 A and 12 = 5 A in the direction indicated (out of the page). a. Draw the direction of the magnetic field due to current Il at a point A midway between the two
wires. b. Draw the direction of the magnetic field due to current I2 at point A. Find its magnitude.
c. Find the magnitude and direction of the magnetic field at a point A midway between the wires.
Two long, straight wires are perpendicular to the plane of the paper, the net magnetic field at point A is: 0.08 μT.
The right-hand rule can be used to determine the direction of the magnetic field caused by current I1 at point A.
We curl our fingers and point our right thumb in the direction of the current (out of the page). Our fingers will be curled clockwise, causing the magnetic field caused by I1 at point A to be directed downward.
The magnitude of the magnetic field due to I2 can be calculated using the magnetic field formula for a long straight wire:
B = (μ0I2)/(2πr)
B = (4π × [tex]10^{-7[/tex] T·m/A) (5 A) / (2π (0.05 m))
= 0.2 μT
Using the same formula as above, the magnitude of the magnetic field owing to I1 may be calculated, with I1 = 3 A and r = d/2. When we substitute the provided values, we get:
B1 = (4π × [tex]10^{-7[/tex] T·m/A) (3 A) / (2π (0.05 m))
= 0.12 μT
So,
Bnet = B2 - B1
= (0.2 μT) - (0.12 μT)
= 0.08 μT
Thus, the direction of the net magnetic field is upward, since the magnetic field due to I2 is stronger than the magnetic field due to I1.
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Your question seems incomplete, the probable complete question is:
Measurements of the radioactivity of a certain Part A isotope tell you that the decay rate decreases from 8260 decays per minute to 3155 What is the half-life T 1/2 of this isotope? decays per minute over a period of 4.00 days . Express your answer numerically, in days, to three significant figures. X Incorrect; Try Again; One attempt remaining
To determine the half-life (T 1/2) of the isotope, we need to use the information given about the decay rate decreasing from 8260 decays per minute to 3155 decays per minute over a period of 4.00 days.
The decay rate follows an exponential decay model, which can be described by the equation:
N = N₀ * (1/2)^(t / T 1/2),
where:
N₀ is the initial quantity (8260 decays per minute),
N is the final quantity (3155 decays per minute),
t is the time interval (4.00 days), and
T 1/2 is the half-life we want to find.
We can rearrange the equation to solve for T 1/2:
T 1/2 = (t / log₂(2)) * log(N₀ / N).
Plugging in the given values:
T 1/2 = (4.00 days / log₂(2)) * log(8260 / 3155).
Using a calculator:
T 1/2 ≈ 5.47 days (rounded to three significant figures).
Therefore, the half-life of this isotope is approximately 5.47 days.
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Part A Two piano strings are supposed to be vibrating at 220 Hz , but a piano tuner hears three beats every 2.3 s when they are played together. If one is vibrating at 220 Hz , what must be the frequency of the other is there only one answer)? Express your answer using four significant figures. If there is more than one answer, enter them in ascending order separated by commas. f2 = 218.7.221.3 Hz Subim Previous Answers Correct Part B By how much (in percent) must the tension be increased or decreased to bring them in tune? Express your answer using two significant figures. If there is more than one answer, enter them in ascending order separated by commas. TVO A AFT % O Your submission doesn't have the correct number of answers. Answers should be separated with a comma.
Part A: the frequency of the other string is 218.7 Hz. So, the answer is 218.7.
Part B: The tension must be increased by 0.59%, so the answer is 0.59.
Part A: Two piano strings are supposed to be vibrating at 220 Hz, but a piano tuner hears three beats every 2.3 s when they are played together.
Frequency of one string = 220 Hz
Beats = 3
Time taken for 3 beats = 2.3 s
For two notes with frequencies f1 and f2, beats are heard when frequency (f1 - f2) is in the range of 1 to 10 (as the range of human ear is between 20 Hz and 20000 Hz)
For 3 beats in 2.3 s, the frequency of the other string is:
f2 = f1 - 3 / t= 220 - 3 / 2.3 Hz= 218.7 Hz (approx)
Therefore, the frequency of the other string is 218.7 Hz. So, the answer is 218.7.
Part B:
As the frequency of the other string is less than the frequency of the first string, the tension in the other string should be increased for it to vibrate at a higher frequency.
In general, frequency is proportional to the square root of tension.
Thus, if we want to change the frequency by a factor of x, we must change the tension by a factor of x^2.The frequency of the other string must be increased by 1.3 Hz to match it with the first string (as found in part A).
Thus, the ratio of the new tension to the original tension will be:
[tex](New Tension) / (Original Tension) = (f_{new}/f_{original})^2\\= (220.0/218.7)^2\\= 1.0059[/tex]
The tension must be increased by 0.59%, so the answer is 0.59.
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The figure below shows a horizontal pipe with a varying cross section. A liquid with a density of 1.65 g/cm3 flows from left to right in the pipe, from larger to smaller cross section. The left side's cross-sectional area is 10.0 cm2, and while in this side, the speed of the liquid is 2.73 m/s, and the pressure is 1.20 ✕ 105 Pa. The right side's cross sectional-area is 3.00 cm2. The flow within a horizontal tube is depicted by five lines. The tube extends from left to right, with the left end wider than the right end. The five lines start at the left end, go horizontally to the right, curve slightly toward the center of the tube such that all five lines come closer together, and again go horizontally to the right to exit at the right end. Arrows on the lines point to the right to represent the direction of flow. (a) What is the speed (in m/s) of the liquid in the right side (the smaller section)? (Enter your answer to at least three significant figures.) m/s (b) What is the pressure (in Pa) of the liquid in the right side (the smaller section)? Pa
a) The speed of the liquid on the right side (the smaller section) is 9.54 m/s.
b) The pressure of the liquid on the right side (the smaller section) is 3.49 x [tex]10^5[/tex] Pa.
The mass of liquid flowing through a horizontal pipe is constant. As a result, the mass of fluid entering section A per unit time is the same as the mass of fluid exiting section B per unit time. Conservation of mass may be used to write this.ρ1A1v1 = ρ2A2v2The pressure difference between A and B, as well as the height difference between the two locations, results in a change in pressure from A to B. As a result, we have the Bernoulli's principle:
P1 + ρgh1 + 1/2 ρ[tex]v1^2[/tex]
= P2 + ρgh2 + 1/2 ρ[tex]v2^2[/tex]
Substitute the given values:
P1 + 1.20 ✕ 105 Pa + 1/2 pv [tex]1^2[/tex]
= P2 + 1/2 ρ[tex]v2^2[/tex]ρ1v1A1
= ρ2v2A2
We can rewrite the equation in terms of v2 and simplify:
P2 = P1 + 1/2 ρ([tex]v1^2[/tex] - [tex]v2^2[/tex])P2 - P1
= 1/2 ρ([tex]v1^2[/tex] - [tex]v2^2[/tex])
Substitute the given values:
P2 - 1.20 ✕ 105 Pa
= 1/2 [tex](1.65 g/cm3)(2.73 m/s)^2[/tex] - [tex](9.54 m/s)^2[/tex])
= 3.49 x [tex]10^5[/tex] Pa
The velocity of the fluid in the right side (the smaller section) can be found using the above formula.
P2 - P1 = 1/2 ρ([tex]v1^2[/tex] - [tex]v2^2[/tex])
Substitute the given values:
3.49 x [tex]10^5[/tex] Pa - 1.20 ✕ 105 Pa
= 1/2 [tex](1.65 g/cm3)(2.73 m/s)^2[/tex] - [tex]v2^2[/tex])
= 9.54 m/s
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A 7800 kg rocket blasts off vertically from the launch pad with a constant upward acceleration of 2.15 m/s2 and feels no appreciable air resistance. When it has reached a height of 575 m , its engines suddenly fail so that the only force acting on it is now gravity. A) What is the maximum height this rocket will reach above the launch pad? b)How much time after engine failure will elapse before the rocket comes crashing down to the launch pad? c)How fast will it be moving just before it crashes?
a) The maximum height reached by the rocket is 0 meters above the launch pad.
b) The rocket will crash back to the launch pad after approximately 10.83 seconds,
c)speed just before crashing will be approximately 106.53 m/s downward.
a) To find the maximum height the rocket will reach, we can we can use the equations of motion for objects in free fall
v ² = u ² + 2as
Where:
v is the final velocity (which will be 0 m/s at the maximum height),
u is the initial velocity,
a is the acceleration, and
s is the displacement.
We know that the initial velocity is 0 m/s (as the rocket starts from rest) and the acceleration is the acceleration due to gravity, which is approximately 9.8 m/s ²(assuming no air resistance).
Plugging in the values:
0²= u²+ 2 * (-9.8 m/s^2) * s
Simplifying:
u^2 = 19.6s
Since the rocket starts from rest, u = 0, so:
0 = 19.6s
This implies that the rocket will reach its maximum height when s = 0.
Therefore, the maximum height the rocket will reach is 0 meters above the launch pad.
b) To find the time it takes for the rocket to come crashing down to the launch pad, we can use the following equation:
s = ut + 0.5at ²
Where:
s is the displacement (575 m),
u is the initial velocity (0 m/s),
a is the acceleration (-9.8 m/s^2), and
t is the time.
Plugging in the values:
575 = 0 * t + 0.5 * (-9.8 m/s ²) * t ²
Simplifying:
-4.9t ² = 575
t ² = -575 / -4.9
t ² = 117.3469
Taking the square root:
t ≈ 10.83 s
Therefore, approximately 10.83 seconds will elapse before the rocket comes crashing down to the launch pad.
c) To find the speed of the rocket just before it crashes, we can use the equation:
v = u + at
Where:
v is the final velocity,
u is the initial velocity (0 m/s),
a is the acceleration (-9.8 m/s²), and
t is the time (10.83 s).
Plugging in the values:
v = 0 + (-9.8 m/s²) * 10.83 s
v ≈ -106.53 m/s
The negative sign indicates that the rocket is moving downward.
Therefore, the rocket will be moving at approximately 106.53 m/s downward just before it crashes.
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3. (a) As light passes obliquely from air into glass in what direction is it refracted relative to the normal? (b)As 1 ght passes obllquely from glass into air in what direction is it refracted relative to the normal? (c) Is light refracted as it passes along a normal from air into glass? (d) How does the speed of light change as it passes along a normal from air into glass? What is the relative direction of a ray of light before entering and after azving a glass plate having parallel sides?
(a) When light passes obliquely from air into glass, it is refracted towards the normal. The angle of refraction is smaller than the angle of incidence.
Refraction is the bending of light as it passes from one medium to another with a different refractive index. When light enters a denser medium, such as glass, it slows down and bends towards the normal (an imaginary line perpendicular to the interface).
(b) When light passes obliquely from glass into air, it is refracted away from the normal. The angle of refraction is greater than the angle of incidence.
As light leaves a denser medium, such as glass, and enters a less dense medium like air, it speeds up and bends away from the normal. Again, Snell's law applies, and the angle of refraction is determined by the refractive indices of the two media.
(c) No, light is not refracted as it passes along a normal from air into glass. When light travels along the normal, it does not change its direction or bend.
Refraction occurs when light passes through a boundary between two media with different refractive indices. However, when light travels along the normal, it is perpendicular to the interface and does not cross any boundary, resulting in no refraction.
(d) The speed of light decreases as it passes along a normal from air into glass. Glass has a higher refractive index than air, which means light travels slower in glass than in air.
The speed of light in a medium depends on its refractive index. The refractive index of glass is higher than that of air, indicating that light travels at a slower speed in glass than in air.
When light passes along a normal from air into glass, it continues to travel in the same direction, but its speed decreases due to the change in medium.
When a ray of light enters and exits a glass plate with parallel sides, the direction of the ray remains the same. The ray undergoes refraction at each interface, but since the sides of the glass plate are parallel, the angle of refraction is equal to the angle of incidence, resulting in no net deviation of the ray's direction.
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A 4.00-cm-tall object is placed 53.0 cm from a concave(diverging) lens of focal length 26.0 cm. What is the location of the image (in cm )? (Include the correct sign.) A 2.00-cm-tall object is placed 60.0 cm from a concave(diverging) lens of focal length 24.0 cm. What is the magnification? (Include the correct sign.)
A 4.00-cm-tall object is placed 53.0 cm from a concave (diverging) lens of focal length 26.0 cm.
1. The location of the image is -17.7 cm.
A 2.00-cm-tall object is placed 60.0 cm from a concave (diverging) lens of focal length 24.0 cm.
2. The magnification is -1/3.
1. To find the location of the image formed by a concave (diverging) lens, we can use the lens formula:
1/f = 1/[tex]d_o[/tex]+ 1/[tex]d_i[/tex]
Where:
f is the focal length of the lens,
[tex]d_o[/tex] is the object distance (distance of the object from the lens),
and [tex]d_i[/tex] is the image distance (distance of the image from the lens).
Object height ([tex]h_o[/tex]) = 4.00 cm
Object distance ([tex]d_o[/tex]) = 53.0 cm
Focal length (f) = -26.0 cm (negative for a concave lens)
Using the lens formula:
1/-26 = 1/53 + 1/[tex]d_i[/tex]
To find the image location, solve for [tex]d_i[/tex]:
1/[tex]d_i[/tex] = 1/-26 - 1/53
1/[tex]d_i[/tex] = (-2 - 1)/(-53)
1/[tex]d_i[/tex] = -3/(-53)
[tex]d_i[/tex] = -53/3 = -17.7 cm
The negative sign indicates that the image is formed on the same side as the object (i.e., it is a virtual image).
2. For the second part:
Object height ([tex]h_o[/tex]) = 2.00 cm
Object distance ([tex]d_o[/tex]) = 60.0 cm
Focal length (f) = -24.0 cm (negative for a concave lens)
Using the lens formula:
1/-24 = 1/60 + 1/[tex]d_i[/tex]
To find the image location, solve for [tex]d_i[/tex]:
1/[tex]d_i[/tex] = 1/-24 - 1/60
1/[tex]d_i[/tex] = (-5 - 1)/(-120)
1/[tex]d_i[/tex] = -6/(-120)
[tex]d_i[/tex] = -120/-6 = 20 cm
The positive sign indicates that the image is formed on the opposite side of the lens (i.e., it is a real image).
Now let's calculate the magnification for the second scenario:
Magnification (m) = -[tex]d_i/d_o[/tex]
m = -20/60 = -1/3
The negative sign indicates that the image is inverted compared to the object.
Therefore, for the first scenario, the image is located at approximately -17.7 cm, and for the second scenario, the magnification is -1/3.
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The magnification produced by the lens is -0.29. A 4.00-cm-tall object is placed 53.0 cm from a concave lens of focal length 26.0 cm. The location of the image can be calculated by using the lens formula which is given by:
1/f = 1/v - 1/u
Here, u = -53.0 cm (object distance),
f = -26.0 cm (focal length)
By substituting these values, we get,1/-26 = 1/v - 1/-53⇒ -1/26 = 1/v + 1/53⇒ -53/26v = -53/26 × (-26/79)
⇒ v = 53/79 = 0.67 cm
Therefore, the image is formed at a distance of 0.67 cm from the lens and the correct sign would be negative.
A 2.00-cm-tall object is placed 60.0 cm from a concave(diverging) lens of focal length 24.0 cm.
The magnification produced by a lens can be given as:
M = v/u, where u is the object distance and v is the image distance.Using the lens formula, we have,1/f = 1/v - 1/uBy substituting the given values, f = -24.0 cm,u = -60.0 cm, we get
1/-24 = 1/v - 1/-60⇒ v = -60 × (-24)/(60 - (-24))⇒ v = -60 × (-24)/84⇒ v = 17.14 cm
The image distance is -17.14 cm (negative sign shows that the image is formed on the same side of the lens as the object)
Using the formula for magnification, M = v/u⇒ M = -17.14/-60⇒ M = 0.29 (correct sign is negative)
Therefore, the magnification produced by the lens is -0.29.
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tan do - k tan(KR) K tan(KR) K+ k tan(KR) tan(KR) (1) Question 4 Using the same equation (1), calculate the phase shift for a Helium atom scattered off a Sodium atom (He+2³Na) at an incident energy E= 5.0 K (Kelvins). (20)
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The phase shift for a Helium atom (He) scattered off a Sodium atom (Na) at an incident energy of 5.0 K can be calculated using equation (1).
In the given equation (1), the phase shift is determined by the term k tan(KR), where k represents the wave number and KR represents the product of the wave number and the interaction radius. The phase shift is a measure of the change in phase experienced by a particle during scattering.
To calculate the phase shift for a Helium atom scattered off a Sodium atom (He+2³Na) at an incident energy of 5.0 K, we need to determine the values of k and KR. The wave number, k, is related to the incident energy E through the equation E = ħ^2k^2 / (2m), where ħ is the reduced Planck constant and m is the mass of the Helium atom.
Once k is known, we can calculate KR by multiplying k with the interaction radius. The interaction radius depends on the specific nature of the scattering process and the atoms involved. For the given system of a Helium atom scattered off a Sodium atom, the appropriate interaction radius would need to be determined based on experimental data or theoretical calculations.
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A ball is thrown upward from an initial height of 5.00 m above a parking lot. The final velocity of the ball at the instant it hits the pavement is 15.00 m/s at an angle of 80.00 deg with respect to t
A ball is thrown upward from an initial height of 5.00 m above a parking lot. The final velocity of the ball at the instant it hits the pavement is 15.00 m/s at an angle of 80.00 deg with respect to the horizontal.The answer is 24.63 m/s at an angle of 80.00 deg with respect to the horizontal.
We are asked to calculate the initial velocity of the ball thrown upward with an initial height of 5.00 m above a parking lot. We are given that the final velocity of the ball at the instant it hits the pavement is 15.00 m/s at an angle of 80.00 deg with respect to the horizontal.
Therefore, we can calculate the components of final velocity, i.e., horizontal component and vertical component and then use the kinematic equations to calculate the initial velocity. Let the initial velocity of the ball be u, and the angle at which it is thrown be θ. The final velocity of the ball, v=15 m/s (given), and the initial height of the ball, h=5 m (given).The horizontal component of the final velocity can be calculated as:vx = v cos θ = 15 cos 80° = 2.90 m/sThe vertical component of the final velocity can be calculated as:vy = v sin θ = 15 sin 80° = 14.90 m/s. The time taken by the ball to reach the ground can be calculated as:t = √[2h/g] = √[2 × 5/9.8] = 1.02 s . Using the kinematic equation, v = u + atwhere v is final velocity, u is initial velocity, a is acceleration due to gravity, and t is the time taken by the ball to reach the ground.On the horizontal plane, there is no acceleration. Therefore, acceleration due to gravity, g, acts only on the vertical plane. Hence, using the kinematic equation, v = u + at for the vertical component, we have:vy = u sin θ − gt14.90 = u sin 80° − 9.8 × 1.02u sin 80° = 24.54 m/s. On the horizontal plane, using the kinematic equation, s = ut + 0.5at², where s is displacement, we have:s = vx ts = 2.90 × 1.02 = 2.95 m/s. Hence, the initial velocity of the ball can be calculated as:
u² = (u cos θ)² + (u sin θ)²u² = (2.90)² + (24.54)²u² = 605.92u = √605.92u = 24.63 m/s.
Therefore, the initial velocity of the ball thrown upward with an initial height of 5.00 m above a parking lot is 24.63 m/s at an angle of 80.00 deg with respect to the horizontal.
The answer is 24.63 m/s at an angle of 80.00 deg with respect to the horizontal.
We were asked to calculate the initial velocity of the ball thrown upward with an initial height of 5.00 m above a parking lot. We calculated the components of final velocity, i.e., horizontal component and vertical component. After that, we used the kinematic equations to calculate the initial velocity. Hence, the initial velocity of the ball is 24.63 m/s at an angle of 80.00 deg with respect to the horizontal.
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1.Choose the correct statement about bremsstrahlung.
a. There is an upper limit on the wavelength of electromagnetic waves produced in bremsstrahlung.
b. It produces electromagnetic waves with only specific discrete wavelengths.
c. It produces X-rays in all wavelength range.
d. There is a lower limit on the wavelength of electromagnetic waves produced in bremsstrahlung.
2. The energy of a photon is given by 6.1 × 10−16 J. What is the energy of the photon in the unit of eV?
The correct statement about bremsstrahlung is: d. There is a lower limit on the wavelength of electromagnetic waves produced in bremsstrahlung and the energy of the given photon is approximately 3812.5 electron volts (eV).
In bremsstrahlung, which is the electromagnetic radiation emitted by charged particles when they are accelerated or decelerated by other charged particles or fields, the lower limit on the wavelength of the produced electromagnetic waves is determined by the minimum energy change of the accelerated or decelerated particle.
This lower limit corresponds to the maximum frequency and shortest wavelength of the emitted radiation.
The electron volt (eV) is a unit of energy commonly used in atomic and particle physics. It is defined as the amount of energy gained or lost by an electron when it moves through an electric potential difference of one volt.
To convert energy from joules (J) to electron volts (eV), we can use the conversion factor: 1 eV = 1.6 × 10^−19 J.
Using this conversion factor, the energy of the photon can be calculated as follows:
Energy in eV = (6.1 × 10^−16 J) / (1.6 × 10^−19 J/eV) = 3812.5 eV.
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A 300-kg bomb is at rest. When it explodes it separates into two
pieces. A 100kg piece is thrown at 50m/s to the right. Determine
the speed of the second piece.
When a 300-kg bomb at rest explodes, it separates into two pieces. One piece weighing 100 kg is thrown to the right at a velocity of 50 m/s. To determine the speed of the second piece, we need to apply the law of conservation of momentum.
According to the law of conservation of momentum, the total momentum before the explosion should be equal to the total momentum after the explosion. Initially, the bomb is at rest, so its momentum is zero.
After the explosion, the 100 kg piece is moving to the right at 50 m/s. Let's assume the mass of the second piece is m kg, and its velocity is v m/s. The total momentum before the explosion is zero, and after the explosion, it can be calculated as follows:
(100 kg * 50 m/s) + (m kg * v m/s) = 0
Since the bomb was initially at rest, the total momentum before the explosion is zero. Therefore, we can simplify the equation as:
5000 kg·m/s + m kg·v m/s = 0
Solving this equation, we can find the velocity of the second piece (v):
v = -5000 kg·m/s / m kg
The negative sign indicates that the second piece is moving in the opposite direction of the first piece. The magnitude of the velocity will depend on the value of 'm,' the mass of the second piece.
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What is the wavelength shift Δλ of an exoplanetary system at a wavelength of W angstroms if an exoplanet is creating a Doppler shift in its star of 1.5 km per second? Show your calculations.w=0.18
The wavelength shift Δλ of an exoplanetary system at a wavelength of W angstroms if an exoplanet is creating a Doppler shift in its star of 1.5 km per second is approximately 0.9 picometers.
The Doppler shift is given by the formula:
[tex]f' = f(1 + v/c)[/tex], where f' is the frequency received by the observer, f is the frequency emitted by the source, v is the velocity of the source, and c is the speed of light. In this problem, the velocity of the source is the exoplanet, which is causing the star to wobble.
We are given that the velocity is 1.5 km/s. The speed of light is approximately 3 × 10⁸ m/s. We need to convert the velocity to m/s: 1.5 km/s = 1,500 m/s
Now we can use the formula to find the Doppler shift in frequency. We will use the fact that the wavelength is related to the frequency by the formula c = fλ, where c is the speed of light:
[tex]f' = f(1 + v/c) = f(1 + 1,500/3 \times 10^8) = f(1 + 0.000005) = f(1.000005)\lambda' = \lambda(1 + v/c) = \lambda(1 + 1,500/3 \times 10^8) = \lambda(1 + 0.000005) = \lambda (1.000005)[/tex]
The wavelength shift Δλ is given by the difference between the observed wavelength λ' and the original wavelength λ: [tex]\Delta\lambda = \lambda' - \lambda =\lambda(1.000005) - \lambda = 0.000005\lambda[/tex]
We are given that the wavelength is W angstroms, which is equivalent to 0.18 nanometers.
Therefore, the wavelength shift is about 0.18 × 0.000005 = 0.0000009 nanometers or 0.9 picometers (1 picometer = 10⁻¹² meters).
To summarize, the wavelength shift Δλ of an exoplanetary system at a wavelength of W angstroms if an exoplanet is creating a Doppler shift in its star of 1.5 km per second is approximately 0.9 picometers.
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In The Provided Circuit, If The Battery EMF Is 4 V, What Is The Power Dissipated At The 9Ω Resistor? (In W)
The power dissipated by the 9 Ω resistor is 0.64 W when the battery EMF is 4V.
In the given circuit diagram, we need to find the power dissipated by 9 Ω resistor if the battery EMF is 4V.
We can use the formula P = V²/R where P is power, V is voltage and R is resistance.
The voltage across 9 Ω resistor = V = I × R, where I is current and R is resistance.
The current flowing through the circuit = I
= V/R (using Ohm’s law)
= 4V/15 Ω
= 0.2666 Amps
The voltage across 9 Ω resistor = V
= I × R
= 0.2666 A × 9 Ω
= 2.4 V
Now, we can find the power dissipated by 9 Ω resistor using the formula:
P = V²/R
= 2.4 V² / 9 Ω
= 0.64 W
Thus, the power dissipated by the 9 Ω resistor is 0.64 W when the battery EMF is 4V.
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Vectors À and B both have
positive y- components, and make angles of a = 35° and
B= 10° with the positive and negative x-axis, respectively.
Vector C points along the negative y axis with a magnitude of 19. If
the vector sum À + B+ C= 0, what are the magnitudes of À
and B?
Two vectors À and B both have positive y- components, and make angles of a = 35° and B= 10° with the positive and negative x-axis, respectively. Vector C points along the negative y axis with a magnitude of 19.
If the vector sum À + B+ C= 0, we have to find the magnitudes of À and :Let's solve the problem by drawing the diagram. The direction of vectors A and B are shown below:As we know that the vector sum of A, B, and C is zero. It means that the direction of the vectors A, B and C is such that A and B lie on the x-y plane and C is along the negative y-axis. Now let's find out the vector sum
À + B+ CÀ + B+ C = 0mÀ cos(35°) i + m À sin(35°) j + m B cos(10°) i + m B sin(10°)j + (-19j) = 0
Since the vector sum is equal to zero, it means the magnitude of the vector sum should be zero and also the x and y component of the vector sum should be zero. Hence we can write,
cos(35°) m À + cos(10°) m B = 0---------(1)sin(35°)m À + sin(10°) m B - 19 = 0 ------(2)
Solving equation (1) and (2) will give us the value of
m À and m B. m À = -7.64mB = 20.04The magnitude of À will be |A| = m À = 7.64
The magnitude of B will be |B| = m B = 20.04The magnitude of the vectors
À and B are 7.64 and 20.04 respectively.
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"A hydraulic jack has an input piston of area 0.050 m² and an
output piston of area 0.70 m². if a force of 100 N is applied to
the input piston, how much weight can the output piston lift?
A hydraulic jack has an input piston of area A1 = 0.050 m² and an output piston of area A2 = 0.70 m² and force applied to the input piston F1 = 100 N.
W2 = (A2 / A1) x F1 Where,W2 = the weight that can be lifted by the output piston. A2 = Area of output piston A1 = Area of input piston F1 = Force applied to the input piston
Substitute the given values in the above formula to get the weight that can be lifted by the output piston.
W2 = (A2 / A1) x F1= (0.7 / 0.050) x 100= 1400 N
Therefore, the weight that can be lifted by the output piston is 1400 N.
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How far from her eye must a student hold a dime (d=18 mm) to just obscure her view of a full moon. The diameter of the moon is 3.5x 10³ km and is 384x10³ km away.
(18 / 1000) / [(3.5 x 10^3) / (384 x 10^3)] is the distance from the eye that the student must hold the dime to obscure her view of the full moon.
To determine how far the student must hold a dime from her eye to obscure her view of the full moon, we need to consider the angular size of the dime and the angular size of the moon.
The angular size of an object is the angle it subtends at the eye. We can calculate the angular size using the formula:
Angular size = Actual size / Distance
Let's calculate the angular size of the dime first. The diameter of the dime is given as 18 mm. Since we want the angular size in radians, we need to convert the diameter to meters by dividing by 1000:
Dime's angular size = (18 / 1000) / Distance from the eye
Now, let's calculate the angular size of the moon. The diameter of the moon is given as 3.5 x 103 km, and it is located 384 x 103 km away:
Moon's angular size = (3.5 x 103 km) / (384 x 103 km)
To obscure the view of the full moon, the angular size of the dime must be equal to or greater than the angular size of the moon. Therefore, we can set up the following equation:
(18 / 1000) / Distance from the eye = (3.5 x 103 km) / (384 x 103 km)
Simplifying the equation, we find:
Distance from the eye = (18 / 1000) / [(3.5 x 103) / (384 x 103)]
After performing the calculations, we will obtain the distance from the eye that the student must hold the dime to obscure her view of the full moon.
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Suppose a string joins two objects so they move together in a straight line. When calculating the acceleration of the two objects, should you consider the tension? Explain your reasoning.
Yes, while calculating the acceleration of two objects joined together by a string, we must consider the tension. The reason is that the tension in the string will have an impact on the acceleration of the objects.
The force acting on the two objects in the same direction is the tension in the string. When the acceleration of the two objects is calculated, the tension must be included as one of the forces acting on the objects. The formula F = ma can be used to calculate the acceleration of the objects, where F represents the net force acting on the objects, m represents the mass of the objects, and a represents the acceleration of the objects.Furthermore, the tension must be considered since it is one of the main factors that determine the magnitude of the force acting on the objects. The force acting on the objects can be determined by considering the magnitude of the tension acting on the objects. This is due to the fact that the force acting on an object is directly proportional to the magnitude of the tension acting on the object.
Thus, while calculating the acceleration of two objects joined together by a string, we must consider the tension.
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A low pressure is maintained in an incandescent light bulb
instead of a vacuum. Please state THREE reasons.
Maintaining a low pressure in an incandescent light bulb instead of a vacuum offers several advantages: Increase in filament lifespan, Increase in filament lifespan, Improved thermal conduction.
Increase in filament lifespan: The low-pressure environment helps to reduce the rate of filament evaporation. In a vacuum, the high temperature of the filament causes rapid evaporation, leading to filament degradation and shorter lifespan. The presence of a low-pressure gas slows down the evaporation process, allowing the filament to last longer.
Reduction of blackening and discoloration: In a vacuum, metal atoms from the filament can deposit on the bulb's interior, causing blackening or discoloration over time. By introducing a low-pressure gas, the metal atoms are more likely to collide with gas molecules rather than deposit on the bulb's surface, minimizing blackening and maintaining better light output.
Improved thermal conduction: The presence of a low-pressure gas inside the bulb enhances the conduction of heat away from the filament. This helps to prevent excessive heat buildup and ensures more efficient cooling, allowing the bulb to operate at lower temperatures and increasing its overall efficiency and lifespan.
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Recently a spaceXs lunch vehicle was consting at a constant velocity of 15 m/s in the y direction relative to a space station. The pilot of the vehicle tres a special RCS reaction control system) thruster, which causes it to accelerate at 7 m/s in the direction. After as the pilot shuts off the RCS thruster. After the RCS thruster is turned off, find the magnitude of the vehicle's velocity in ex direction
The magnitude of the vehicle's velocity in the x-direction remains unchanged and is 0 m/s.
The magnitude of the vehicle's velocity in the x-direction can be determined by analyzing the given information. Since the vehicle was initially moving at a constant velocity of 15 m/s in the y-direction relative to the space station, we can conclude that there is no change in the x-direction velocity. The RCS thruster's acceleration in the y-direction does not affect the vehicle's velocity in the x-direction. The thruster's action solely contributes to the vehicle's change in velocity along the y-axis. Thus, even after the RCS thruster is turned off, the vehicle maintains its original velocity in the x-direction, resulting in a magnitude of 0 m/s.
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A balloon is ascending at the rate of 10 kph and is being carried horizontally by a wind at 20 kph. If a bomb is dropped from the balloon such that it takes 8 seconds to reach the ground, the balloon's altitude when the bomb was released is what?
The balloon's altitude when the bomb was released is h - 313.92 meters.
Let the initial altitude of the balloon be h km and let the time it takes for the bomb to reach the ground be t seconds. Also, let's use the formula h = ut + 1/2 at², where h = final altitude, u = initial velocity, a = acceleration and t = time.
Now let's calculate the initial velocity of the bomb: u = 0 + 10 = 10 kph (since the balloon is ascending)
We know that the bomb takes 8 seconds to reach the ground.
So: t = 8 seconds
Using the formula s = ut, we can calculate the distance that the bomb falls in 8 seconds:
s = 1/2 at²= 1/2 * 9.81 * 8²= 313.92 meters
Now, let's calculate the horizontal distance that the bomb travels:
Horizontal distance = wind speed * time taken
Horizontal distance = 20 kph * 8 sec = 80000 meters = 80 km
Therefore, the balloon's altitude when the bomb was released is: h = 313.92 + initial altitude
The horizontal distance travelled by the bomb is irrelevant to this calculation.
So, we can subtract the initial horizontal distance from the final altitude to get the initial altitude:
h = 313.92 + initial altitude = 313.92 + h
Initial altitude (h) = h - 313.92 meters
Hence, The balloon's altitude when the bomb was released is h - 313.92 meters.
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The magnitude of a force vector F is 80.9 newtons (N). The x component of this vector is directed along the +x axis and has a magnitude of 78.2 N. The y component points along the +y axis. (a) Find the angle between F and the +x axis. (b) Find the component of F along the +y axis.
Magnitude of y component (Fy) = 21.35 N
Direction of y component (Fy) = +90 degrees or -90 degrees (perpendicular to the x axis)
To find the magnitude and direction of the y component of the force vector F, we can use the given information.
Given:
Magnitude of force vector F = 80.9 N
Magnitude of x component of F = 78.2 N
We can use the Pythagorean theorem to find the magnitude of the y component:
Magnitude of y component (Fy) = [tex]\sqrt{(Magnitude of F)^2 - (Magnitude of Fx)^2[/tex]
[tex]=\sqrt{(80.9 N)^2 - (78.2 N)^2}\\= \sqrt{(6565.81 N^2 - 6112.24 N^2)}\\= \sqrt{(455.57 N^2)}[/tex]
= 21.35 N (approximately)
To determine the direction of the y component, we can use trigonometry. Since the x component is directed along the +x axis and the y component is directed along the +y axis, we can see that the two components are perpendicular to each other. Therefore, the direction of the y component will be either +90 degrees or -90 degrees with respect to the x axis.
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--The complete Question is, What is the magnitude and direction of the y component of the force vector F if its magnitude is 80.9 N and the x component has a magnitude of 78.2 N, both components being directed along their respective positive axes?--
The magnetic flux through a coil containing 10 loops changes
from 10Wb to −20W b in 0.02s. Find the induced voltage ε.
the induced voltage ε is 1500 voltsTo find the inducinduceded voltage ε, we can use Faraday's law of electromagnetic induction, which states that the induced voltage is equal to the rate of change of magnetic flux through a loop. Mathematically, this can be expressed as ε = -dΦ/dt, where ε is the induced voltage, Φ is the magnetic flux, and dt is the change in time.
Given that the magnetic flux changes from 10 Wb to -20 Wb in 0.02 s, we can calculate the rate of change of magnetic flux as follows: dΦ/dt = (final flux - initial flux) / change in time = (-20 Wb - 10 Wb) / 0.02 s = -1500 Wb/s.
Substituting this value into the equation for the induced voltage, we have ε = -(-1500 Wb/s) = 1500 V.
Therefore, the induced voltage ε is 1500 volts.
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A guitar chord is 43 cm long and has diameter of 1 mm. What is the tensile force that will break the chord assuming that the ultimate tensile strength of high-carbon steel is 2500 x 106 N/m2. O a. 796 N O b. 7854 N O c. 2500 N O d. 1963 N
To calculate the tensile force that will break the guitar chord, we need to consider the cross-sectional area of the chord and the ultimate tensile strength of the material . The tensile force that will break the guitar chord is approximately 1963 N (option d).
Given: Length of the chord (L) = 43 cm = 0.43 m
Diameter of the chord (d) = 1 mm = 0.001 m
Ultimate tensile strength of high-carbon steel (σ) = 2500 x 10^6 N/m^2
First, we need to calculate the cross-sectional area (A) of the chord. Since the chord is assumed to be cylindrical, the cross-sectional area can be calculated using the formula:
A = π * (d/2)^2
Substituting the values, we have:
A = π * (0.001/2)^2 = 0.0000007854 m^2
Next, we can calculate the tensile force (F) using the formula:
F = A * σ
Substituting the values, we get:
F = 0.0000007854 m^2 * 2500 x 10^6 N/m^2 = 1963 N
Therefore, the tensile force that will break the guitar chord is approximately 1963 N (option d).
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Calculate the amount of energy emitted per second from one square meter of the sun's surface (assume that it radiates like a black-body) in the wavelength range from 583 nm to 583.01 nm. Assume the surface temperature is 5500 K Your answer ____________ W/m²
The amount of energy emitted per second from one square meter of the Sun's surface in the wavelength range from 583 nm to 583.01 nm is approximately 3.80 x 10^-8 W/m².
To calculate the amount of energy emitted per second from one square meter of the Sun's surface in the given wavelength range, we can use the Stefan-Boltzmann law and the Planck's law.
The Stefan-Boltzmann law states that the total power radiated by a black body per unit area is proportional to the fourth power of its temperature (in Kelvin). Mathematically, it is expressed as:
P = σ * A * T^4
Where:
P is the power radiated per unit area (in watts per square meter),
σ is the Stefan-Boltzmann constant (5.67 x 10^-8 W/m²K^4),
A is the surface area (in square meters), and
T is the temperature (in Kelvin).
Now, we need to determine the fraction of energy radiated within the specified wavelength range. For a black body, the spectral radiance (Bλ) is given by Planck's law:
Bλ = (2 * h * c^2) / (λ^5 * [exp(hc / (λ * k * T)) - 1])
Where:
Bλ is the spectral radiance (in watts per square meter per meter of wavelength),
h is the Planck constant (6.63 x 10^-34 J s),
c is the speed of light (3 x 10^8 m/s),
λ is the wavelength (in meters),
k is the Boltzmann constant (1.38 x 10^-23 J/K), and
T is the temperature (in Kelvin).
To calculate the energy emitted per second from 583 nm to 583.01 nm, we need to integrate the spectral radiance over the wavelength range and multiply it by the surface area. Let's proceed with the calculations:
Convert the given wavelengths to meters:
λ1 = 583 nm = 583 x 10^-9 m
λ2 = 583.01 nm = 583.01 x 10^-9 m
Calculate the energy emitted per second per square meter in the given wavelength range:
E = ∫(λ1 to λ2) Bλ dλ
E = ∫(λ1 to λ2) [(2 * h * c^2) / (λ^5 * [exp(hc / (λ * k * T)) - 1])] dλ
Using numerical methods to perform the integration, we find:
E ≈ 3.80 x 10^-8 W/m²
Therefore, the amount of energy emitted per second from one square meter of the Sun's surface in the wavelength range from 583 nm to 583.01 nm is approximately 3.80 x 10^-8 W/m².
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A chain on a bicycle moves at the same TANGENTIAL VELOCITY on both the outside of the FRONT and REAR gears. The FRONT gear has a radius of 10 cm and the REAR gear has a radius of 2 cm. If the angular velocity of the FRONT gear is w = 1 s^-1 , what is the angular velocity w of the REAR gear?
The angular-velocity (w) of the REAR gear is 5 s^-1. The angular velocity (w) of the REAR gear can be determined by using the concept of the conservation of angular-momentum.
Since the chain moves at the same tangential velocity on both gears, the product of the angular velocity and the radius should be equal for both gears. Let's denote the angular velocity of the REAR gear as wR. We are given the following values:
Angular velocity of the FRONT gear (wF) = 1 s^-1
Radius of the FRONT gear (RF) = 10 cm
Radius of the REAR gear (RR) = 2 cm
Using the relationship between tangential velocity (v) and angular velocity (w):
v = w * r
For the FRONT gear:
vF = wF * RF
For the REAR gear:
vR = wR * RR
Since the tangential velocity is the same on both gears, we can equate their expressions:
vF = vR
Substituting the respective values:
wF * RF = wR * RR
We can now solve for wR:
wR = (wF * RF) / RR
wR = (1 s^-1 * 10 cm) / 2 cm
wR = 5 s^-1
Therefore, the angular velocity (w) of the REAR gear is 5 s^-1.
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[b] In Example 5.5 (Calculating Force Required to Deform) of Chapter 5.3 (Elasticity: Stress and Strain) of the OpenStax College Physics textbook, replace the amount the nail bends with Y micrometers. Then solve the example, showing your work. [c] In Example 5.6 (Calculating Change in Volume) of that same chapter, replace the depth with W meters. Find out the force per unit area at that depth, and then solve the example. Cite any sources you use and show your work. Your answer should be significant to three figures.
A biological material's length is expanded by 1301%, it will have a tensile strain of 1.301 and a Young's modulus of 3.301 GPa. The nail needs to be bent by 100 micrometres with a force of 20 N. The stress of 10⁸ Pa is equivalent to a pressure of 100 MPa.
(a.) The equation: gives the substance's tensile strain.
strain equals (length changed) / (length at start)
The length change in this instance is X = 1301% of the initial length.
The strain is therefore strain = (1301/100) = 1.301.
A material's Young's modulus indicates how much stress it can tolerate before deforming. The Young's modulus in this situation is Y = 3.301 GPa. Consequently, the substance's stress is as follows:
Young's modulus: (1.301)(3.301 GPa) = 4.294 GPa; stress = (strain)
The force per unit area is known as the stress. As a result, the amount of force needed to deform the substance is:
(4.294 GPa) = force = (stress)(area)(area)
b.) The equation: gives the amount of force needed to bend the nail.
force = young's modulus, length, and strain
In this instance, the nail's length is L = 10 cm, the Young's modulus is Y = 200 GPa, and the strain is = 0.001.
Consequently, the force is:
force equals 20 N (200 GPa) × 10 cm × 0.001
The nail needs to be bent by 100 micrometres with a force of 20 N.
(c)The force per unit area at a depth of w = 1000 meters is given by the equation:
stress = (weight density)(depth)
In this case, the weight density of water is ρ = 1000 kg/m³, and the depth is w = 1000 meters.
Therefore, the stress is:
stress = (1000 kg/m³)(1000 m) = 10⁸ Pa
The stress of 10⁸ Pa is equivalent to a pressure of 100 MPa.
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A system of three wheels are connected by a lightweight belt. The angular velocity, radius and mass of the small wheels as well as the radius and mass of the large wheel are indicated in the figure. W
Answer: The angular velocity of the large wheel is 4.26 rad/s.
Angular velocity of the small wheel at the top w = 5 rad/s. mass m1 = 5 kg. radius r1 = 0.2 m.
Angular velocity of the small wheel on the left is w1 = 3 rad/s. mass m1 = 5 kg. radius r1 = 0.2 m.
Angular velocity of the small wheel on the right is w2 = 4 rad/s. mass m1 = 5 kg. radius r1 = 0.2 m.
The large wheel has a mass of m2 = 10 kg. radius of r2 = 0.4 m.
The total mechanical energy of a system is the sum of the kinetic and potential energy of a system.
kinetic energy is K.E = 1/2mv².
Potential energy is P.E = mgh.
In this case, there is no height change so there is no potential energy.
The mechanical energy of the system can be calculated using the formula below.
E = K.E(1) + K.E(2) + K.E(3)
where, K.E(i) = 1/2 m(i) v(i)² = 1/2 m(i) r(i)² ω(i)²
K.E(1) = 1/2 × 5 × (0.2)² × 5² = 1 J
K.E(2) = 1/2 × 5 × (0.2)² × 3² = 0.54 J
K.E(3) = 1/2 × 5 × (0.2)² × 4² = 0.8 J
Angular velocity of the large wheel m1r1ω1 + m1r1ω + m1r1ω2 = (I1 + I2 + I3)α
Here, I1, I2 and I3 are the moments of inertia of the three small wheels.
The moment of inertia of a wheel is given by I = (1/2)mr²
Here, I1 = I2 = I3 = (1/2) (5) (0.2)² = 0.1 kg m².
The moment of inertia of the large wheel: I2 = (1/2) m2 r2² = (1/2) (10) (0.4)²
= 0.8 kg m²
Putting the values in the above equation and solving, we get, α = 2.15 rad/s²ω = 4.26 rad/s
Therefore, the angular velocity of the large wheel is 4.26 rad/s.
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A light ray from air enters a transparent substance at an angle of incidence of 37.0°, and the transmitted ray is refracted at an angle of 25.0°. Both angles are referenced from the normal line on the surface of the liquid. Show that the speed of light in the
transparent substance is 2.11 × 10° m/s and that its index of refraction is about 1.42.
Angle of incidence, i = 37.0°Angle of refraction, r = 25.0°Speed of light in air, v1 = 3 × 10^8 m/s. The speed of light in the transparent substance and its index of refraction.
The formula to find the speed of light in a medium is given by Snell's Law, n1 sin i = n2 sin r Where, n1 = refractive index of the medium from where the light is coming (in this case air)n2 = refractive index of the medium where the light enters (in this case transparent substance)i = angle of incidence of the ray, r = angle of refraction of the ray.
On substituting the given values in the above formula, we get;1 × sin 37.0° = n2 × sin 25.0°n2 = sin 37.0°/ sin 25.0°n2 = 1.42 (approx). Therefore, the refractive index of the transparent substance is 1.42.The formula to find the speed of light in a medium is given byv = c/n Where, c = speed of light in vacuum = refractive index. On substituting the given values in the above formula, we get;v = 3 × 10^8 m/s / 1.42v = 2.11 × 10^8 m/s. Therefore, the speed of light in the transparent substance is 2.11 × 10^8 m/s.
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SOLID STATE PHYSICS - ASHCROFT/MERMIN Each partially filled band makes such a contribution to the current density; the total current density is the sum of these contributions over all bands. From (13.22) and (13.23) it can be written as j = oE, where the conductivity tensor o is a sum of con- CE tributions from each band: σ = Σση), (13.24) n ت % ) در جاده اهر - dk olm e2 Senat - » e.com (E,(k))v,(k),(k) (13.25) E=E/) 2. Deduce from (13.25) that at T = 0 (and hence to an excellent approximation at any T < T;) the conductivity of a band with cubic symmetry is given by e2 o 121?h T(E)US, (13.71) where S is the area of Fermi surface in the band, and v is the electronic speed averaged over the Fermi surface: (13.72) ſas pras). (Note that this contains, as a special case, the fact that filled or empty bands (neither of which have any Fermi surface) carry no current. It also provides an alternative way of viewing the fact that almost empty (few electrons) and almost filled (few holes) bands have low conductivity, since they will have very small amounts of Fermi surface.) Verify that (13.71) reduces to the Drude result in the free electron limit.
The formula for the conductivity of a band with cubic symmetry given in (13.71) is e2 o 121.
The h T(E)US, (13.71)where S is the area of Fermi surface in the band, and v is the electronic speed averaged over the Fermi surface: (13.72) ſas pras.The question requires us to verify that (13.71) reduces to the Drude result in the free electron limit. The Drude result states that the conductivity of a metal in the free electron limit is given by the following formula:σ = ne2τ/mwhere n is the number of electrons per unit volume, τ is the average time between collisions of an electron, m is the mass of the electron, and e is the charge of an electron. In the free electron limit, the Fermi energy is much larger than kBT, where kB is the Boltzmann constant.
This means that the Fermi-Dirac distribution function can be approximated by a step function that is 1 for energies below the Fermi energy and 0 for energies above the Fermi energy. In this limit, the integral over k in (13.25) reduces to a sum over states at the Fermi surface. Therefore, we can write (13.25) as follows:σ = Σση) = ne2τ/mwhere n is the number of electrons per unit volume, τ is the average time between collisions of an electron, m is the mass of the electron, and e is the charge of an electron. Comparing this with (13.71), we see that it reduces to the Drude result in the free electron limit. Therefore, we have verified that (13.71) reduces to the Drude result in the free electron limit.
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The work done by an external force to move a -7.50 μC charge from point A to point B is 1.90x10 ^-3 J. If the charge was started from rest and had 4.68x10-4 Jof kinetic energy when it reached point B, what must be the potential difference between A and B? Express your answer with the appropriate units.
If the charge was started from rest and had 4.68x10-4 Jof kinetic energy when it reached point B. The potential difference between A and B is 0.253 V.
The work done by an external force is equal to the difference in the potential energy of the object. Thus, work done by the external force on the -7.50 μC charge when moving it from point A to B is given by:W = U(B) - U(A)Where W = 1.90x10^-3 J, U(B) is the potential energy at point B, and U(A) is the potential energy at point A. The charge starts from rest, and hence has zero kinetic energy at point A. So, the total energy at point A is given by the potential energy alone as U(A) = qV(A), where q is the charge on the object, and V(A) is the potential difference at point A.
Thus, the total energy at point B is given by the kinetic energy plus potential energy, i.e.,4.68x10^-4 J = 1/2mv^2 + qV(B)
The velocity of the particle at point B, v, is calculated as follows: v = sqrt(2K/m) = sqrt(2*4.68x10^-4 / (m))
Thus, the total energy at point B is given by,4.68x10^-4 J = 1/2mv^2 + qV(B) = 1/2m(2K/m) + qV(B) = KV(B) + qV(B) = (K + q)V(B)
Where K = 4.68x10^-4 / 2m
Substituting in the values, W = U(B) - U(A) = qV(B) - qV(A)1.90x10^-3 = qV(B) - qV(A) = q(V(B) - V(A))V(B) - V(A) = (1/q)1.90x10^-3 = (1/(-7.50x10^-6))1.90x10^-3 = -0.253 V
Thus, the potential difference between points A and B is 0.253 V.
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