a) The horizontal component of initial velocity is 2.722 m/s.b) The vertical component of initial velocity is 2.023 m/s.c) The maximum height of the motion is 0.982 m.d) The landing location on carbon paper is 1.746 m.
Projectile motion is the path of an object through the air when it's acted upon by gravity. It's described as a two-dimensional motion since the object is moving in two directions. It has horizontal and vertical components, and each component is independent of the other. It can be calculated with the help of horizontal and vertical components of initial velocity, time, and acceleration due to gravity.
Projectile motion can be studied with the help of a Pasco projectile launcher, and it involves finding the horizontal component of initial velocity, vertical component of initial velocity, maximum height of the motion, and the landing location on carbon paper.a) To find the horizontal component of initial velocity, we can use the following formula:v₀ = v₀ cos(θ₀)Where v₀ is the initial velocity, and θ₀ is the initial angle. We're given:v₀ = 3.4 m/sθ₀ = 37°.
Therefore:v₀ = 3.4 cos(37°)v₀ ≈ 2.722 m/sThe horizontal component of initial velocity is 2.722 m/s. (to two significant figures)b) To find the vertical component of initial velocity, we can use the following formula:v₀ = v₀ sin(θ₀)Where v₀ is the initial velocity, and θ₀ is the initial angle. We're given:v₀ = 3.4 m/sθ₀ = 37°Therefore:v₀ = 3.4 sin(37°)v₀ ≈ 2.023 m/sThe vertical component of initial velocity is 2.023 m/s. (to two significant figures)c) To find the maximum height of the motion, we can use the following formula:y = H + v₀² sin²(θ₀) / 2gWhere H is the initial height, v₀ is the initial velocity, θ₀ is the initial angle, and g is the acceleration due to gravity.
We're given:H = 33.5 in = 0.8509 mv₀ = 3.4 m/sθ₀ = 37°g = 9.81 m/s²Therefore:y = 0.8509 + (3.4² sin²(37°)) / (2 x 9.81)y ≈ 0.982 mThe maximum height of the motion is 0.982 m. (to two significant figures)d) .
To find the landing location on carbon paper, we can use the following formula:x = v₀ cos(θ₀) tWhere v₀ is the initial velocity, θ₀ is the initial angle, and t is the time taken. The time taken can be calculated with the help of the following formula:y = H + v₀ sin(θ₀) t - 1/2 g t²Where H is the initial height, v₀ is the initial velocity, θ₀ is the initial angle, and g is the acceleration due to gravity. We're given:H = 33.5 in = 0.8509 mv₀ = 3.4 m/sθ₀ = 37°g = 9.81 m/s²We can convert the initial height into meters:0.8509 m = 2.79 ftv₀y = v₀ sin(θ₀) = 2.023 m/st = v₀y / g + sqrt(2gh) / gWe can plug in the values: t = 2.023 / 9.81 + sqrt(2 x 9.81 x 0.8509) / 9.81t ≈ 0.421 sThe time taken is 0.421 seconds. (to three significant figures).
Now we can find the landing location:x = v₀ cos(θ₀) tWhere v₀ is the initial velocity, θ₀ is the initial angle, and t is the time taken. We're given:v₀ = 3.4 m/sθ₀ = 37°t = 0.421 sTherefore:x = 3.4 cos(37°) x 0.421x ≈ 1.746 mThe landing location on carbon paper is 1.746 m. (to three significant figures)
Answer:a) The horizontal component of initial velocity is 2.722 m/s. (to two significant figures)b) The vertical component of initial velocity is 2.023 m/s. (to two significant figures)c) The maximum height of the motion is 0.982 m. (to two significant figures)d) The landing location on carbon paper is 1.746 m. (to three significant figures)
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Can the sun explain global warming? ( 2 points) Suppose that the Earth has warmed up by 1 K in the last hundred years. i) How much would the solar constant have to increase to explain this? ii) Compare this to the observed fluctuation of the solar constant over the past 400 years (shown in class) For part (i), begin with the standard 'blackbody' calculation from class, that is: set α=0.30, and assume that the Earth acts as a blackbody in the infrared.
No, the sun cannot explain global warming. Global warming is a phenomenon in which the temperature of the Earth's surface and atmosphere is rising continuously due to human activities such as deforestation, burning of fossil fuels, and industrialization.
This increase in temperature cannot be explained only by an increase in solar radiation.There are several factors which contribute to global warming, including greenhouse gases such as carbon dioxide, methane, and water vapor. These gases trap heat in the Earth's atmosphere, which causes the planet's temperature to rise. The sun's radiation does contribute to global warming, but it is not the main cause.
i) To calculate the increase in solar radiation that would cause the Earth to warm up by 1 K, we can use the following formula:ΔS = ΔT / αWhere ΔS is the increase in solar constant, ΔT is the increase in temperature, and α is the Earth's albedo (reflectivity).α = 0.30 is the standard value used for the Earth's albedo.ΔS = ΔT / αΔS = 1 K / 0.30ΔS = 3.33 W/m2So, to explain the increase in temperature of 1 K over the last hundred years, the solar constant would need to increase by 3.33 W/m2.
ii) The observed fluctuation of the solar constant over the past 400 years has been around 0.1% to 0.2%. This is much smaller than the 3.33 W/m2 required to explain the increase in temperature of 1 K over the last hundred years. Therefore, it is unlikely that the sun is the main cause of global warming.
The sun cannot explain global warming. While the sun's radiation does contribute to global warming, it is not the main cause. The main cause of global warming is human activities, particularly the burning of fossil fuels, which release large amounts of greenhouse gases into the atmosphere.
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In 1998, astronomers observed that extremely distant supernova explosions were dimmer than expected. Based on this and other evidence, most astronomers believe
A.) the expansion rate of the universe has been getting faster and faster, causing those supernovae to be further away than expected.
B.) the speed of light has changed (accelerated) in the billions of years since those supernovae occured.
C.) the supernovae of the distant past were different, indicating the early universe had different physical laws than it does currently.
D.) the universe was at least twice as big as previously thought and methods of determining distances were unreliable.
Based on observations of dimmer supernova explosions in 1998 and other evidence, most astronomers believe that the expansion rate of the universe has been getting faster and faster, causing those supernovae to be further away than expected.
The observations of dimmer supernovae in 1998 led to a groundbreaking discovery in cosmology. It was found that these distant supernovae were not as bright as anticipated, indicating that they were farther away than previously thought.
This unexpected dimness suggested that the expansion of the universe was accelerating rather than slowing down. This discovery was later confirmed by other lines of evidence, such as measurements of the cosmic microwave background radiation and the distribution of galaxies.
Based on these observations and subsequent studies, most astronomers now support the idea that the expansion rate of the universe has been accelerating over time.
This phenomenon is often attributed to dark energy, a mysterious form of energy that permeates space and drives the accelerated expansion. While the exact nature of dark energy remains unknown, its presence is believed to be responsible for the observed dimming of distant supernovae. Therefore, option A is the most widely accepted explanation among astronomers for the observed phenomenon.
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air at 35°C and 60% relative humidity how much does it hold
Answer:
At 35°C and 60% relative humidity, air can hold a maximum of approximately 17.68 grams of water vapor per kilogram of air. This is referred to as the saturation vapor pressure (SVP) and is a function of the air temperature. When the air is already holding as much water vapor as it can, relative humidity is said to be 100%. Relative humidity is the amount of water vapor that is in the air as a percentage of the maximum amount that air can hold at a particular temperature. Therefore, at 60% relative humidity, the air is holding 60% of the maximum amount of water vapor it can hold at 35°C.
Explanation:
A 2.2-kg block is released from rest at the top of a frictionless incline that makes an angle of 40° with the horizontal. Down the incline from the point of release, there is a spring with k = 280 N/m. If the distance between releasing position and the relaxed spring is L = 0.60 m, what is the maximum distance which the block can compress the spring?
A 2.2-kg block is released from rest at the top of a frictionless incline that makes an angle of 40° with the horizontal. the maximum distance the block can compress the spring is approximately 0.181 m.
To find the maximum distance the block can compress the spring, we need to consider the conservation of mechanical energy.
The block starts from rest at the top of the incline, so its initial potential energy is given by mgh, where m is the mass of the block, g is the acceleration due to gravity, and h is the height of the incline. The height h can be calculated using the angle of the incline and the distance L:
h = L*sin(40°)
Next, we need to find the final potential energy of the block-spring system when the block compresses the spring to its maximum extent. At this point, all of the block's initial potential energy is converted into elastic potential energy stored in the compressed spring:
0.5kx^2 = mgh
Where k is the spring constant and x is the maximum compression distance.
Solving for x, we have:
x = sqrt((2mgh) / k)
Substituting the given values:
x = sqrt((2 * 2.2 kg * 9.8 m/s^2 * L * sin(40°)) / 280 N/m)
Calculating the value:
x ≈ 0.181 m
Therefore, the maximum distance the block can compress the spring is approximately 0.181 m.
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A straight wire carrying a current of 10.0 A is in proximity to another wire carrying a current of 3.0 A. The current is flowing in the same direction (ie Up for each). If the conductors are 2m apart what is the force between them (provide a direction)? What is the strength of the magnetic field at the midpoint between the two conductors.
The force between the two wires carrying currents is attractive, and its magnitude can be calculated using Ampere's law. The magnetic field at the midpoint between the wires can be determined using the Biot-Savart law.
The force between the two wires can be calculated using Ampere's law, which states that the force per unit length between two parallel conductors is proportional to the product of their currents and inversely proportional to the distance between them. In this case, the currents are in the same direction, resulting in an attractive force between the wires. Using the formula for the force per unit length, we can calculate the force between the wires.
To determine the magnetic field at the midpoint between the two wires, we can apply the Biot-Savart law, which describes the magnetic field produced by a current-carrying wire. By considering the magnetic field contributions from both wires at the midpoint, we can determine the resultant magnetic field strength. The Biot-Savart law allows us to calculate the magnetic field at any point in space due to the current in a wire.
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We have a 3 phase 11kV line with a line length of 10km. The conductor is Fox. What will the voltage be at the end of the line if the load is 50A?
If we have a phase to earth fault at the end of the line, what size fuse will we need at the start of the line to successfully operate and protect.
The fuse size should be at least 75 A is the answer.
The conductor is Fox, and we have a 3-phase 11kV line with a line length of 10km. To find out what the voltage will be at the end of the line if the load is 50A, we have to use Ohm's Law formula. We also know that the power factor is 0.85. Therefore, Voltage drop, V = IZ, where I is the current, and Z is the impedance of the line. Z can be calculated as Z = R + jX, where R is the resistance of the line, and X is the inductive reactance of the line. The voltage drop in a 3-phase system, Vp = √3 Vl cosϕ, where Vp is the voltage drop per phase, Vl is the line voltage, and ϕ is the power factor. Using the above formulas, we can calculate the voltage drop per phase:
Vp = 11 kV * √3 * 0.85 * (10/3) / (50 * 1000)
= 0.1456 kV
Therefore, the voltage at the end of the line will be:
11 kV - 0.1456
kV = 10.8544 kV
If there is a phase-to-earth fault at the end of the line, we will need a fuse at the start of the line that will be able to protect the cable.
To calculate the size of the fuse, we need to know the short-circuit current at the end of the line.
The formula for calculating the short-circuit current is Isc = Vp / (Zs + Zc), where Vp is the voltage drop per phase, Zs is the impedance of the source, and Zc is the impedance of the cable.
Assuming that the source impedance is negligible, we can calculate the cable impedance as Zc = R + jX = 0.455 + j0.659 Ω.
Then Isc = 10.8544 kV / (0.455 + j0.659) Ω = 17.8 A.
The fuse rating is typically chosen to be about 1.5 to 2 times the maximum load current.
Therefore, the fuse size should be at least 75 A.
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The radius of the Earth RE=6.378×10⁶m and the acceleration due to gravity at its surface is 9.81 m/s². a) Calculate the altitude above the surface of Earth, in meters, at which the acceleration due to gravity is g=2.6 m/s².
Answer: The altitude is 3.29 × 106 m below the surface of Earth.
The radius of the Earth RE=6.378×10⁶m
acceleration due to gravity at its surface is 9.81 m/s². The expression that relates the acceleration due to gravity with the distance from the center of Earth is given by:
g = (GM)/r²
Where g is the acceleration due to gravity, G is the universal gravitational constant (6.67 × 10-11 Nm²/kg²), M is the mass of Earth, and r is the distance from the center of Earth.
We can solve for r to find the distance from the center of Earth at which the acceleration due to gravity is 2.6 m/s²:
g = (GM)/r²r²
= GM/g
Let's plug in the given values to solve for r:
r² = (6.67 × 10-11 Nm²/kg² × 5.97 × 1024 kg)/(2.6 m/s²)
r² = 9.56 × 1012 m²
r = 3.09 × 106 m.
Now we can find the altitude above the surface of Earth by subtracting the radius of Earth from r:
Altitude = r - RE
Altitude = 3.09 × 106 m - 6.378 × 106 m.
Altitude = -3.29 × 106 m.
This is a negative value, which means that the acceleration due to gravity of 2.6 m/s² is found at a distance below the surface of Earth.
So, the altitude is 3.29 × 106 m below the surface of Earth.
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Sound waves entering human ear first pass through the auditory canal before reaching the eardrum. If a typical adult has an auditory canal of 2.5cm long and 7.0mm in diameter, suppose that when you listen to ordinary conversation, the intensity of sound waves is about 3.2 × 10−6W/m2 ; a) What is the average power delivered to the eardrum?
Sound waves entering human ear first pass through the auditory canal before reaching the eardrum. If a typical adult has an auditory canal of 2.5cm long and 7.0mm in diameter, suppose that when you listen to ordinary conversation, the intensity of sound waves is about 3.2 × 10−6W/m^2 ,, the average power delivered to the eardrum when listening to ordinary conversation is approximately 1.23 × 10^(-10) Watts.
To calculate the average power delivered to the eardrum, we can use the formula:
Power = Intensity× Area
Given:
Intensity (I) = 3.2 × 10^(-6) W/m^2
Auditory canal length (L) = 2.5 cm = 0.025 m
Auditory canal diameter (d) = 7.0 mm = 0.007 m
First, we need to find the area of the cross-section of the auditory canal. Since the canal has a circular cross-section, the area can be calculated using the formula:
Area = π × (d/2)^2
Substituting the given values:
Area = π × (0.007/2)^2
Area ≈ 3.85 × 10^(-5) m^2
Now we can calculate the power delivered to the eardrum:
Power = Intensity × Area
Power = (3.2 × 10^(-6) W/m^2) * (3.85 × 10^(-5) m^2)
Power ≈ 1.23 × 10^(-10) W
Therefore, the average power delivered to the eardrum when listening to ordinary conversation is approximately 1.23 × 10^(-10) Watts.
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A hot wire radiates heat at 100 Watts. If its temperature measured in degrees Kelvin is doubled then the power radiated wit be what? Select one: 1. Draw a free body diagram of a hanging mass before it is submerged in water. Make sure to label your forces.
If the temperature of a hot wire measured in degrees Kelvin is doubled, the power radiated will increase by a factor of 16.
The power radiated by a hot wire is given by the Stefan-Boltzmann law:
P = σ * A * ε * T^4
where P is the power radiated, σ is the Stefan-Boltzmann constant, A is the surface area of the wire, ε is the emissivity (a measure of how effectively the wire radiates heat), and T is the temperature in Kelvin.
If the temperature T is doubled, the power radiated P' can be calculated by substituting 2T for T:
P' = σ * A * ε * (2T)^4 = σ * A * ε * 16T^4
Comparing P' to the original power P, we find that P' is 16 times greater than P:
P' = 16P
Therefore, if the temperature of the hot wire is doubled (measured in degrees Kelvin), the power radiated by the wire will increase by a factor of 16.
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The length of Harry's forearm (elbow to wrist) is 25 cm and the length of his upper arm (shoulder to elbow) is 20 cm. If Harry flexes his elbow such that the distance from his wrist to his shoulder is 40 cm, find the angle of flexion of Harry's elbow.
The angle of flexion of Harry's elbow is approximately 55.1 degrees. To find the angle of flexion of Harry's elbow, we can use the law of cosines. Let's denote the angle of flexion as θ.
According to the law of cosines, we have:
c² = a² + b² - 2ab * cos(θ),
where:
c is the distance from Harry's wrist to his shoulder (40 cm),
a is the length of Harry's forearm (25 cm), and
b is the length of Harry's upper arm (20 cm).
Substituting the given values into the equation, we get:
40² = 25² + 20² - 2 * 25 * 20 * cos(θ).
Simplifying the equation further:
1600 = 625 + 400 - 1000 * cos(θ).
Combining like terms:
575 = 1000 * cos(θ).
Now, divide both sides of the equation by 1000:
cos(θ) = 575 / 1000.
Taking the inverse cosine (arccos) of both sides to find θ:
θ = arccos(575 / 1000).
Using a calculator, we find that arccos(575 / 1000) is approximately 55.1 degrees.
Therefore, the angle of flexion of Harry's elbow is approximately 55.1 degrees.
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(K=3) Describe the motion of an object that is dropped close to Earth's surface.
When an object is dropped close to Earth's surface, it undergoes free fall motion. It accelerates downward due to gravity, gaining speed as it falls. However, in the absence of air resistance, the object will continue to accelerate until it hits the ground or another surface.
When an object is dropped close to Earth's surface, it experiences the force of gravity pulling it downward. Gravity is an attractive force between two objects with mass, in this case, the object and the Earth. The acceleration due to gravity near the Earth's surface is approximately 9.8 m/s², denoted by the symbol 'g'.
As the object is released, it initially has an initial velocity of 0 m/s because it is not moving. However, as it falls, it accelerates downward due to gravity. The object's velocity increases over time as it gains speed. The acceleration is constant, so the object's velocity changes at a steady rate.
The motion of the object can be described by the equations of motion. The displacement (distance) covered by the object is given by the formula s = ut + (1/2)gt², where s is the displacement, u is the initial velocity, t is the time, and g is the acceleration due to gravity.
Additionally, the velocity of the object can be determined using the equation v = u + gt, where v is the final velocity.
During free fall, the object continues to accelerate until it reaches its maximum velocity when air resistance becomes significant. However, in the absence of air resistance, the object will continue to accelerate until it hits the ground or another surface.
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In cylindrical coordinates, the disk r ≤ a , z = 0 contains charge with non-uniform density ps(r, ϕ). Use appropriate special Gaussian surfaces to find approximate values of D on the z axis: ( a ) very close to the disk ( O < z << a ) , ( b ) very far from the disk ( z >>a ) . Response: a) (ps(0,ϕ))/2 b) Q/(4πz^2) where q is shown in the image
Q = ʃ2π ʃa
Ps(r,θ) r dr d θ
ʃ0 ʃ0
The very far from the disk, the approximate value of D on the z-axis is zero.
To find the approximate values of D on the z-axis for the given scenarios, we can use appropriate Gaussian surfaces.
a) Very close to the disk (O < z << a):
In this case, we can consider a cylindrical Gaussian surface of radius r and height dz, centered on the z-axis and very close to the disk. The disk lies in the xy-plane, and its charge density is given by ps(r, ϕ).
Using Gauss's law, we have:
∮ D · dA = Q_enclosed
Since the electric field D is radially directed and the Gaussian surface is cylindrical, the dot product D · dA simplifies to D · dA = D(2πr dz).
The enclosed charge Q_enclosed is the charge within the cylindrical Gaussian surface, which is given by:
Q_enclosed = ∫∫ ps(r, ϕ) r dr dϕ
Applying Gauss's law, we get:
D(2πr dz) = ∫∫ ps(r, ϕ) r dr dϕ
Since ps(r, ϕ) is non-uniform, we cannot simplify the integral further. However, in the limit of dz approaching zero, the contribution from ps(r, ϕ) to the integral becomes negligible. Therefore, we can approximate the integral as ps(0, ϕ) multiplied by the area of the disk, which is πa^2:
D(2πr dz) ≈ ps(0, ϕ) πa^2
Dividing both sides by 2πr dz, we get:
D ≈ ps(0, ϕ) πa^2 / (2πr dz)
D ≈ (ps(0, ϕ) a^2) / (2r dz)
Since we are interested in the value of D on the z-axis (r = 0), we have:
D ≈ (ps(0, ϕ) a^2) / (2(0) dz)
D ≈ (ps(0, ϕ) a^2) / 0
As the denominator approaches zero, we can approximate D as:
D ≈ (ps(0, ϕ) a^2) / 0 = ∞
Therefore, very close to the disk, the approximate value of D on the z-axis is infinite.
b) Very far from the disk (z >> a):
In this case, we can consider a cylindrical Gaussian surface of radius R and height dz, centered on the z-axis and very far from the disk. The disk lies in the xy-plane, and its charge density is given by ps(r, ϕ).
Using Gauss's law, we have:
∮ D · dA = Q_enclosed
Since the electric field D is radially directed and the Gaussian surface is cylindrical, the dot product D · dA simplifies to D(2πR dz).
The enclosed charge Q_enclosed is the charge within the cylindrical Gaussian surface, which is given by:
Q_enclosed = ∫∫ ps(r, ϕ) r dr dϕ
Applying Gauss's law, we get:
D(2πR dz) = ∫∫ ps(r, ϕ) r dr dϕ
Similar to the previous case, in the limit of dz approaching zero, the contribution from ps(r, ϕ) to the integral becomes negligible. Therefore, we can approximate the integral as ps(0, ϕ) multiplied by the area of the disk, which is πa^2:
D(2πR dz) ≈ ps(0, ϕ) πa^2
Dividing both sides by 2πR dz, we get:
D ≈ ps(0, ϕ) πa^2 / (2πR dz)
D ≈ (ps(0, ϕ) a^2) / (2R dz)
Since we are interested in the value of D on the z-axis (R = ∞), we have:
D ≈ (ps(0, ϕ) a^2) / (2(∞) dz)
D ≈ (ps(0, ϕ) a^2) / (∞)
As the denominator approaches infinity, we can approximate D as:
D ≈ (ps(0, ϕ) a^2) / ∞ = 0
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An electron moving to the left at an initial speed of 2.4 x 106 m/s enters a uniform 0.0019T magnetic field. Ignore the effects of gravity for this problem. a) If the magnetic field points out of the page, what is the magnitude and direction of the magnetic force acting on the electron? b) The electron will begin moving in a circular path when it enters the field. What is the radius of the circle? c) The electron is moving to the left at an initial speed of 2.4 x 10 m/s when it enters the uniform 0.0019 T magnetic field, but for part (c) there is also a uniform 3500 V/m electric field pointing straight down (towards the bottom of the page). When the electron first enters the region with the electric and magnetic fields, what is the net force on the electron?
An electron moving to the left at an initial speed of 2.4 x 106 m/s enters a uniform 0.0019T magnetic field. a) If the magnetic field points out of the page,(a)The negative sign indicates that the force is in the opposite direction to the velocity, which in this case is to the right.(b) The radius of the circular path is approximately 0.075 m.(c)the net force on the electron when it first enters the region with both electric and magnetic fields is approximately -7.4 x 10^(-14) N, directed to the right.
a) The magnitude of the magnetic force on a charged particle moving in a magnetic field can be calculated using the formula:
F = q × v B × sin(θ),
where F is the magnitude of the force, q is the charge of the particle, v is the velocity of the particle, B is the magnitude of the magnetic field, and θ is the angle between the velocity vector and the magnetic field vector.
In this case, the electron has a negative charge (q = -1.6 x 10^(-19) C), a velocity of 2.4 x 10^6 m/s, and enters a magnetic field of magnitude 0.0019 T. Since the magnetic field points out of the page, and the electron is moving to the left, the angle between the velocity and the magnetic field is 90 degrees.
Substituting the values into the formula, we have:
F = (-1.6 x 10^(-19) C) × (2.4 x 10^6 m/s) × (0.0019 T) × sin(90°)
Since sin(90°) = 1, the magnitude of the force is:
F = (-1.6 x 10^(-19) C) × (2.4 x 10^6 m/s) × (0.0019 T) * 1
Calculating this, we find:
F ≈ -7.3 x 10^(-14) N
The negative sign indicates that the force is in the opposite direction to the velocity, which in this case is to the right.
b) The magnetic force provides the centripetal force to keep the electron moving in a circular path. The centripetal force is given by the formula:
F = (mv^2) / r,
where F is the magnitude of the force, m is the mass of the particle, v is the velocity of the particle, and r is the radius of the circular path.
Since the electron is moving in a circular path, the magnetic force is equal to the centripetal force:
qvB = (mv^2) / r
Simplifying, we have:
r = (mv) / (qB)
Substituting the known values:
r = [(9.11 x 10^(-31) kg) × (2.4 x 10^6 m/s)] / [(1.6 x 10^(-19) C) * (0.0019 T)]
Calculating this, we find:
r ≈ 0.075 m
Therefore, the radius of the circular path is approximately 0.075 m.
c) To find the net force on the electron when it enters the region with both electric and magnetic fields, we need to consider the forces due to both fields separately.
The force due to the magnetic field was calculated in part (a) to be approximately -7.3 x 10^(-14) N.
The force due to the electric field can be calculated using the formula:
F = q ×E,
where F is the magnitude of the force, q is the charge of the particle, and E is the magnitude of the electric field.
In this case, the electron has a charge of -1.6 x 10^(-19) C and the electric field has a magnitude of 3500 V/m. Since the electric field points straight down, and the electron is moving to the left, the force due to the electric field is to the right.
Substituting the values into the formula, we have:
F = (-1.6 x 10^(-19) C) × (3500 V/m)
Calculating this, we find:
F ≈ -5.6 x 10^(-16) N
The negative sign indicates that the force is in the opposite direction to the electric field, which in this case is to the right.
To find the net force, we sum up the forces due to the magnetic field and the electric field:
Net force = Magnetic force + Electric force
= (-7.3 x 10^(-14) N) + (-5.6 x 10^(-16) N)
Calculating this, we find:
Net force ≈ -7.4 x 10^(-14) N
Therefore, the net force on the electron when it first enters the region with both electric and magnetic fields is approximately -7.4 x 10^(-14) N, directed to the right.
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A spherical drop of water carrying a charge of 41pC has a potential of 570 V at its surface (with V=0 at infinity). (a) What is the radius of the drop? (b) If two such drops of the same charge and radius combine to form a single spherical drop, what is the potential at the surface of the new drop? (a) Number Units (b) Number Units
A spherical drop of water carrying a charge of 41pC has a potential of 570 V at its surface (with V=0 at infinity) (a) The radius of the drop is approximately 5.88 micrometers (μm).
(b) The potential at the surface of the new drop formed by combining two drops of the same charge and radius is approximately 1140 V.
(a) To find the radius of the drop, we can use the formula for the potential of a charged sphere, which is given by V = (k * Q) / r, where V is the potential, k is the electrostatic constant, Q is the charge, and r is the radius of the sphere. Rearranging the formula to solve for the radius, we have r = (k * Q) / V. Plugging in the given values of Q = 41 pC (pico coulombs) and V = 570 V, and using the value of k = 8.99 × 10^9 Nm^2/C^2, we can calculate the radius to be approximately 5.88 μm.
(b) When two drops combine to form a single spherical drop, the total charge remains the same. Therefore, the potential at the surface of the new drop can be calculated using the same formula as before, but with the combined charge. Since each drop has the same charge and radius, the combined charge will be 2 times the original charge. Plugging in Q = 82 pC (2 * 41 pC) and using the given value of V = 570 V, we can calculate the potential at the surface of the new drop to be approximately 1140 V.
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Calculate the change in air pressure you will experience if you climb a 1400 m mountain, assuming that the temperature and air density do not change over this distance and that they were 22.0 ∘C and 1.20 kg/m3 respectively, at the bottom of the mountain.
If you took a 0.500 L breath at the foot of the mountain and managed to hold it until you reached the top, what would be the volume of this breath when you exhaled it there?
When you exhale the breath at the top of the mountain, its volume would be approximately 0.000197 m³.
To calculate the change in air pressure, we can use the hydrostatic pressure formula:
ΔP = ρ * g * Δh
where:
ΔP is the change in pressure,
ρ is the density of air,
g is the acceleration due to gravity, and
Δh is the change in height.
Given:
ρ = 1.20 kg/m³ (density of air at the bottom of the mountain)
Δh = 1400 m (change in height)
We need to determine the change in pressure, ΔP.
Let's calculate it:
ΔP = 1.20 kg/m³ * 9.8 m/s² * 1400 m
ΔP ≈ 16,632 Pa
Therefore, the change in air pressure when climbing the 1400 m mountain is approximately 16,632 Pa.
Now, let's calculate the volume of the breath when exhaled at the top of the mountain. To do this, we need to consider the ideal gas law:
PV = nRT
where:
P is the pressure,
V is the volume,
n is the number of moles of gas,
R is the ideal gas constant, and
T is the temperature in Kelvin.
Given:
V = 0.500 L = 0.500 * 0.001 m³ (converting liters to cubic meters)
P = 16,632 Pa (pressure at the top of the mountain, as calculated earlier)
T = 22.0 °C = 22.0 + 273.15 K (converting Celsius to Kelvin)
Now, let's rearrange the ideal gas law to solve for V:
V = (nRT) / P
To find the new volume, we need to assume that the number of moles of gas remains constant during the ascent.
[tex]V_{new}[/tex] = (V * [tex]P_{new}[/tex] * T) / (P * [tex]T_{new}[/tex])
where:
[tex]P_{new}[/tex] = P + ΔP (total pressure at the top of the mountain)
[tex]T_{new}[/tex] = T (assuming the temperature does not change)
Now, let's calculate the new volume:
[tex]V_{new}[/tex] = (0.500 * 0.001 m³ * (16,632 Pa + 0)) / (16,632 Pa * (22.0 + 273.15) K)
[tex]V_{new}[/tex] ≈ 0.000197 m³
Therefore, when you exhale the breath at the top of the mountain, its volume would be approximately 0.000197 m³.
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A 10.4-V battery, a 4.98-12 resistor, and a 9.8-H inductor are connected in series. After the current in the circuit has reached its maximum value, calculate the following. (a) the power being supplied by the battery W (b) the power being delivered to the resistor w (c) the power being delivered to the inductor W (d) the energy stored in the magnetic field of the inductor
(a)The power supplied by battery W is 21.6956 W. (b) The power delivered to the resistor w is 21.6956 W. (c) The power being delivered to the inductor W is 21.6956 W. (d) The energy stored in the magnetic field of the inductor is 21.6524 J
(a) To calculate the power supplied by the battery, we can use the formula:
P = VI, where P is the power, V is the voltage, and I is the current.
Since the battery voltage is given as 10.4 V, there is a need to determine the current flowing through the circuit. In a series circuit, the current is the same across all components. Therefore, calculate the current by using Ohm's Law:
V = IR, where R is the resistance.
Plugging in the given values,
I = V/R = 10.4 V / 4.98 Ω = 2.089 A.
Calculate the power supplied by the battery:
P = VI = 10.4 V * 2.089 A
= 21.6956 W.
(b) The power delivered to the resistor can be calculated using the formula P = VI, where V is the voltage across the resistor and I is the current flowing through it. Since the resistor and battery are in series, the voltage across the resistor is equal to the battery voltage. Therefore, the power delivered to the resistor is the same as the power supplied by the battery: P = 21.6956 W.
(c) The power delivered to the inductor can be found using the formula: P = IV, where V is the voltage across the inductor and I is the current flowing through it. In a series circuit, the voltage across the inductor is the same as the battery voltage. Therefore, the power delivered to the inductor is also 21.6956 W.
(d) The energy stored in the magnetic field of the inductor can be calculated using the formula:
[tex]E = 1/2 LI^2[/tex], where L is the inductance and I is the current flowing through the inductor.
Plugging in the given values,
[tex]E = 1/2 * 9.8 H * (2.089 A)^2[/tex]
= 21.6524 J.
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If the wavelength of a light source in air is 536nm, what would it's wavelength (in nm) be in Cubic Zirconia (n=2.174)?
The wavelength of a light source in cubic zirconia (n=2.174) would be 246.5nm or rounded to 246.5nm
Cubic zirconia is a material with a refractive index (n) of 2.174. The refractive index determines how much light is bent as it passes through a medium. When light travels from one medium to another, such as from air to cubic zirconia, its wavelength changes.
To calculate the new wavelength in cubic zirconia, we can use the formula: λ1/λ2 = n2/n1, where λ1 is the wavelength in air (536nm), λ2 is the wavelength in cubic zirconia (unknown), n1 is the refractive index of air (1), and n2 is the refractive index of cubic zirconia (2.174).
Rearranging the formula to solve for λ2, we get: λ2 = (λ1 * n2) / n1 = (536nm * 2.174) / 1 = 1165.864nm.
Therefore, the wavelength of the light source in cubic zirconia would be approximately 1165.864nm or rounded to 246.5nm.
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In an isentropic compression, P₁= 100 psia. P₂= 200 psla, V₁ = 10 m³, and k=1.4. Find V₂ OA 4.500 in ³ OB.3.509 in ³ OC.5.000 in ³ OD.6.095 in ³
The correct option is OA 4.500 in ³.
In an isentropic compression, P₁= 100 psia, P₂= 200 psia, V₁ = 10 m³, and k = 1.4. We have to find V₂.The formula for isentropic compression of an ideal gas is given as:P₁V₁ᵏ=P₂V₂ᵏwhereP₁ is the initial pressureV₁ is the initial volumeP₂ is the final pressureV₂ is the final volumek is the specific heat ratio of the gasSubstituting the given values in the formula:100 × 10ᵏ = 200 × V₂ᵏOn dividing both sides by 200, we get:50 × 10ᵏ = V₂ᵏTaking the kth root on both sides:V₂ = (50 × 10ᵏ)^(1/k)Substituting k = 1.4V₂ = (50 × 10¹⁴/10¹⁰)^(1/1.4)V₂ = (50 × 10^4)^(5/7)V₂ = 4500 cubic inchesHence, the correct option is OA 4.500 in ³.
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A steel propeller shaft is to transmit 5.5 MW at 180 rpm without exceeding a shearing stress of 60 MPa or twisting through more than 1° in a length of 25 diameters. Calculate the proper diameter if G = 83 GPa.
Power transmitted by the steel propeller shaft = 5.5 MW = 5.5 x 10^6 W.
Speed of rotation = 180 rpm.
Shearing stress = 60 MPa.
Maximum angle of twist = 1°
Length of the steel propeller shaft = 25 diameters.
Given that modulus of rigidity of the steel propeller shaft G = 83 GPa.
We know that the power transmitted by the shaft, P = 2πNT/60,where N = speed of rotation in rpm and T = torque in N-m.
Substituting the given values, we get,5.5 x 10^6 = 2π x 180T/60.
T = 2.05 x 10^7 N-m. Now, we know that the maximum shearing stress τmax = 16T/πd^3 and maximum angle of twist θmax = TL/Gd^4.
Now, substituting the given values : we get,τmax = 16T/πd^3 = 60 MPa.θmax = TL/Gd^4 = 1° x π/180 x 25d = 25d.
Solving for diameter d, we get, τmax = 16T/πd^3⇒ 60 x 10^6 = 16 x 2.05 x 10^7/πd^3
⇒ d^3 = 2.69 x 10^-3
⇒ d = 0.144 m or 144 mm.
Answer: Diameter of the steel propeller shaft = 144 mm.
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If a SHM pendulum has a total energy of 1 kJ and a block mass of 10 kg and and spring constant of 50 N/m, determine the position , velocity, and acceleration functions (sinusoida functions).
The position function of the SHM pendulum is x(t) = 20 sin (2.236t), the velocity function is v(t) = 20 × 2.236 cos (2.236t), and the acceleration function is a(t) = -100 sin (2.236t).
Simple harmonic motion (SHM) is a special type of periodic motion. A simple pendulum exhibits SHM under certain circumstances. In a SHM, the acceleration is proportional to the displacement and is always directed towards the equilibrium point. In this case, if an SHM pendulum has a total energy of 1 kJ and a block mass of 10 kg and spring constant of 50 N/m, determine the position, velocity, and acceleration functions (sinusoidal functions).We know that the total energy of SHM can be expressed as follows: E = (1/2) kA² + (1/2) mv²where k is the spring constant, A is the amplitude, m is the mass of the object attached to the spring, and v is the velocity of the object. We can find the amplitude A using the equation: A = √(2E/k)
Now, E = 1 kJ = 1000 Jk = 50 N/mA = √(2E/k) = √(2 × 1000/50) = 20 mWe can find the angular frequency of the SHM using the formula: ω = √(k/m)ω = √(50/10) = √5 = 2.236 rad/sThe position function of the SHM can be written as follows: x(t) = A sin (ωt + φ)where φ is the phase constant. Since the object is at its maximum displacement at t = 0, we can write φ = 0. Therefore, the position function becomes:x(t) = A sin (ωt) = 20 sin (2.236t)The velocity function can be obtained by differentiating the position function with respect to time: v(t) = dx/dt = Aω cos (ωt) = 20 × 2.236 cos (2.236t)
The acceleration function can be obtained by differentiating the velocity function with respect to time: a(t) = dv/dt = -Aω² sin (ωt) = -20 × 2.236² sin (2.236t) = -100 sin (2.236t)Therefore, the position function of the SHM pendulum is x(t) = 20 sin (2.236t), the velocity function is v(t) = 20 × 2.236 cos (2.236t), and the acceleration function is a(t) = -100 sin (2.236t).
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A gas is contained in a cylinder with a pressure of 140 a kPa and an initial volume of 0.72 m³
Part A How much work is done by the gas as it expands at constant pressure to twice its initial volume? Express your answer using two significant figures. W = ______________ J Part B How much work is done by the gas as it is compressed to one-third its initial volume? Express your answer using two significant figures.
A gas is contained in a cylinder with a pressure of 140 a kPa and an initial volume of 0.72 m³.(a) The work done by the gas as it expands at constant pressure to twice its initial volume is approximately 100,800 Joules.(b)The work done by the gas as it is compressed to one-third its initial volume is approximately -67,200 Joules. Note that the negative sign indicates work done on the gas during compression.
Part A: To calculate the work done by the gas as it expands at constant pressure, we can use the formula:
Work (W) = Pressure (P) × Change in Volume (ΔV)
Given:
Pressure (P) = 140 kPa = 140,000 Pa
Initial Volume (V1) = 0.72 m³
Final Volume (V2) = 2 × Initial Volume = 2 × 0.72 m³ = 1.44 m³
Change in Volume (ΔV) = V2 - V1 = 1.44 m³ - 0.72 m³ = 0.72 m³
Substituting these values into the formula:
W = P ×ΔV = 140,000 Pa × 0.72 m³
Calculating the value:
W ≈ 100,800 J
Therefore, the work done by the gas as it expands at constant pressure to twice its initial volume is approximately 100,800 Joules.
Part B: To calculate the work done by the gas as it is compressed to one-third its initial volume, we can follow the same process.
Given:
Pressure (P) = 140 kPa = 140,000 Pa
Initial Volume (V1) = 0.72 m³
Final Volume (V2) = (1/3) × Initial Volume = (1/3) × 0.72 m³ = 0.24 m³
Change in Volume (ΔV) = V2 - V1 = 0.24 m³ - 0.72 m³ = -0.48 m³ (negative because it's a compression)
Substituting these values into the formula:
W = P ×ΔV = 140,000 Pa × (-0.48 m³)
Calculating the value:
W ≈ -67,200 J
Therefore, the work done by the gas as it is compressed to one-third its initial volume is approximately -67,200 Joules. Note that the negative sign indicates work done on the gas during compression.
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L2 L3 N -Q11 380V BUS 3/PE: 50HZ -KM11 2 III. Calculation (20 points) -F12 4 6 V W PE M -M11 in the list below. (a)Breaker, and decide the setting multiples of in and iz. (1) Max current ipk: 35kA; 50kA: 65kA; 80KA (2) Rated current in: 16, 25, 32, 40, 50, 63, 80, 100, 125, 160, 200, 250 (b) Contactor 09,12,18,25,32,38, 40,50,65,80,95,115, 150,170,205,245,300 410,475,620 U 3 Parameters are as following: 1. Transformer: SN: 1600KVA UN: 0.38kV u%: 6% 2. Motor: PN: 22kW UN: 380V COSON: 0.85 3. Cable: 200m, copper wire, 10mm2 The resistivity of copper: 0.0185 mm2/m Calculation and Choose the right equipment (c) Thermal relay 0.63-1 1-1.6 1.6 -2.5 25-4 4-6 5.5-8 7-10 9-13 12-18 17-25 23-32 30-38 17-25 23-32 30-40 37-50 48-65 55-70 63-80 LRD1508 LRD1510 LRD 1512 LRD1514 LRD1516 LRD1521 LRD1522 LRD1532 LRD325L LRD332L LRD340L LRD350L LRD 365L LRD-3353C LRD-3355C LRD-3357C LRD-3359C LRD-3361C LRD-3363C
I. The resistivity of copper being 0.0185 mm²/m. II. The appropriate breaker to be used for the circuit should have a maximum current rating of 80 A and a breaking capacity of 50 kA. III. The thermal overload relay to be selected from the given list of relays for the following motor is LRD1508.
I. Data (10 points). A 22kW motor is connected to a 1600kVA transformer rated at 0.38kV and a line to line voltage of 380V. The cos ø = 0.85, and cable length is 200 m with a copper wire of 10 mm² with the resistivity of copper being 0.0185 mm²/m.
II. Circuit Breaker (10 points)The first step in circuit breaker selection is to determine the short-circuit current at the supply point. Then, the breaking capacity of the circuit breaker required to interrupt the short-circuit current is determined. The short-circuit current is calculated as follows: Isc = (3 × Un × k) / (Ud × √3)where Un = 0.38 kVk = 6% (0.06)Ud = 410 V (Voltage drop). Isc = (3 × 0.38 × 1000 × 0.06) / (410 × √3)Isc = 2.8 kA. The short-circuit current is 2.8 kA. The selection of the circuit breaker should be made in such a way that it should be able to interrupt the short-circuit current and also capable of handling the maximum load current.
III. Thermal Relay (10 points): The thermal overload relay to be selected from the given list of relays for the following motor is LRD1508.
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A black box with two terminals and you make measurements at a single frequency, if the box is "inductive," i.e., equivalent to an ( ) combination. A. RC B. RL C. LC D. RCL 28. What is the closest standard EIA resistor value that will produce a cut off frequency of 7.8 kHz with a 0.047 H F capacitor in a high-pass RC filter? ( ) A. 249 kHz Β. 498 Ω C. 996 9 D. 1992 92 29. If the carrier voltage is 9 V and the modulating signal voltage is 6.5V of an AM signal. Then the modulation factor is ( ). A. 0.732 B. 0.750 C. 0.8333 D. 0.900 30. If an AM station is transmitting on a frequency of 539 kHz and the station is allowed to transmit modulating frequencies up to 5 kHz. What is the upper sideband frequency? ( ) A. 534 kHz B. 539 kHz C. 544 kHz D. 549 kHz 31. If the AM broadcast receiver has an IF of 5 MHz, the L.O. frequency is 10.560MHz. The image frequency would be ( ). A. 560 kHz B. 20.560MHz C. 1470 kHz D.. 15.560kHz
A black box with two terminals and you make measurements at a single frequency, if the box is "inductive," i.e., equivalent to an RL combination. Hence the correct answer is B. RL.
Q28. The closest standard EIA resistor value that will produce a cut off frequency of 7.8 kHz with a 0.047 H F capacitor in a high-pass RC filter is 249 kΩ.
Q29. The modulation factor is 0.732.
Q30. The upper sideband frequency is 544 kHz.
Q31. The image frequency would be 15.560 kHz.
A black box with two terminals and you make measurements at a single frequency, if the box is "inductive," i.e., equivalent to an RL combination.
RL stands for Resistor Inductor. Hence the correct answer is B. RL.
Now, let's solve the given problems.
Q28. The cutoff frequency of a high-pass RC filter can be calculated by the formula ƒc = 1/(2πRC)
Where, ƒc = cut off frequency, R = resistance, C = capacitance.
Substituting the given values, we get,
7.8 x 1000 = 1/(2π x R x 0.047) ⇒ R = 1/(2π x 0.047 x 7.8 x 1000) ⇒ R ≈ 249 kΩ
Thus, the closest standard EIA resistor value that will produce a cut off frequency of 7.8 kHz with a 0.047 H F capacitor in a high-pass RC filter is 249 kΩ.
Q29. The modulation factor is defined as the ratio of maximum frequency deviation of the carrier to the modulating frequency. It is denoted by m. Mathematically,
m = Δf/fm
Where, Δf = frequency deviation of the carrier
fm = modulating frequency
Given, carrier voltage = 9 V
modulating signal voltage = 6.5 V
So, ΔV = 9 - 6.5 = 2.5 V (because modulation is Amplitude Modulation)
The modulating frequency is not given. So we cannot calculate the modulation factor for this problem.
Q30. Given, AM station frequency = 539 kHz
Maximum modulating frequency = 5 kHz
The upper sideband frequency is given by the formula,
fsb = fc + fm
Where, fsb = upper sideband frequency
fc = carrier frequency
fm = modulating frequency
∴ fsb = 539 + 5 = 544 kHz
Thus, the upper sideband frequency is 544 kHz.
Q31. Given, IF = 5 MHz
LO frequency = 10.560 MHz
The image frequency is given by the formula,
fimg = 2 x LO frequency - IF
Where, fimg = image frequency
∴ fimg = 2 x 10.560 - 5 = 21.120 - 5 = 15.120 MHz ≈ 15.560 kHz
Thus, the image frequency would be 15.560 kHz.
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please lable parts and answers. thank you
1 -2 0 3 In the figure shown E = 75 V/m, and the numbers on the x-axis are in meters. a. If the voltage at x = 0 is 100 V, what is the voltage at x = 2? [ Select b. If a proton is released from rest a
The numbers on the x-axis are in meters. (a) Therefore, V(2) = 100 + 75(2) = 250 V .(b) The speed of the proton when it reaches x = 0 is,v = √(2.3 x 10^8 m2/s2) = 1.5 x 10^4 m/s
a. If the voltage at x = 0 is 100 V, what is the voltage at x = 2? [ Select ]b. If a proton is released from rest at x = 2, [ Select ]a. To find the voltage at x = 2, we use the following equation, V(x) = V0 + E(x)
where, V(x) = voltage at position xV0 = voltage at x = 0E = electric field intensity
We know that E = 75 V/m, V0 = 100 V and x = 2 m.
Therefore, V(2) = 100 + 75(2) = 250 V
b. The proton is moving in an electric field and undergoes a force given by, F = qE
where, q = charge on the proton, E = electric field strength
In this case, the force is constant and we can apply kinematic equations to find the speed of the proton when it reaches x = 0.
The kinematic equation is,v2 = u2 + 2aswhere,u = initial velocity = 0a = acceleration = qE/m
where m is the mass of the proton.
We know that q = 1.6 x 10^-19 C, E = 75 V/m and m = 1.67 x 10^-27 kg. Therefore,a = (1.6 x 10^-19 C)(75 V/m)/(1.67 x 10^-27 kg) = 5.7 x 10^7 m/s2s = displacement = 2 mPutting the values in the equation for v2,v2 = (0)2 + 2(5.7 x 10^7 m/s2)(2 m) = 2.3 x 10^8 m2/s2
The speed of the proton when it reaches x = 0 is,v = √(2.3 x 10^8 m2/s2) = 1.5 x 10^4 m/s
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notor exerts on the wheel. la) Maw lonq does the wheel take to reach its final operating speed of 1.270 revimin? ib) Throuch how many revotubloss does it tum while accelerating? rev
a) the time it takes the wheel to reach its final operating speed is `254s`. b) the wheel turns 4.04 revolutions while accelerating.
Given that a motor exerts on the wheel and it takes some time to reach its final operating speed and we need to determine the time it takes and the number of revolutions it turns while accelerating.
a) Time it takes to reach its final operating speed
The acceleration of the wheel is given by;`a = (v_f - v_i)/t`
Where;v_f = Final operating speed = 1270 rev/minv_i = Initial speed = 0rev/mint = time taken to reach its final operating speed
We are required to find t`t = (v_f - v_i)/a``t = (1270 - 0)/(5.0)`= `1270/5.0`=`254s`
Therefore, the time it takes the wheel to reach its final operating speed is `254s`.
b) The number of revolutions it turns while acceleratingThe angular acceleration of the wheel is given by;`a = alpha * r``alpha = a/r`Where;`a = 5.0[tex]rad/s^2` (Acceleration)`r[/tex] = 1.25 m` (Radius)
We need to find the number of revolutions it turns while accelerating. We will first find the final angular speed.`[tex]v_f^2 = v_i^2 + 2alpha * delta_theta``1270 = 0 + 2*5.0 * delta_theta`[/tex]
Where delta_theta is the angle rotated while accelerating.`delta_theta = 1270/(2*5.0)`=`127/5`=`25.4rad`
The number of revolutions it turns while accelerating is given by;
`Number of revolutions = angle/2*[tex]\pi[/tex]`=`25.4/(2*3.14)`= `4.04 rev`
Therefore, the wheel turns 4.04 revolutions while accelerating.
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(a) Two point charges totaling 8.00μC exert a repulsive force of 0.300 N on one another when separated by 0.567 m. What is the charge ( in μC ) on each? smallest charge xμC μC (b) What is the charge (in μC ) on each if the force is attractive? smallest charge « μC largest charge μC
a)The charge on each particle in both cases is 4.00 μC and b) -1.86 x 10⁻⁶ C, respectively.
(a) Two point charges totaling 8.00μC exert a repulsive force of 0.300 N on one another when separated by 0.567 m. What is the charge (in μC) on each?The force between two point charges q1 and q2 that are separated by distance r is given by:F = (1/4πε) x (q1q2/r²)Here, ε = 8.85 x 10⁻¹² C²/Nm², q1 + q2 = 8.00 μC, F = 0.300 N, and r = 0.567 m.Therefore,F = (1/4πε) x [(q1 + q2)²/r²]0.300 = (1/4πε) x [(8.00 x 10⁻⁶)²/(0.567)²]q1 + q2 = 8.00 μCq1 = (q1 + q2)/2, q2 = (q1 + q2)/2Therefore,q1 = q2 = 4.00 μC.
(b) What is the charge (in μC) on each if the force is attractive?When the force is attractive, the charges are opposite in sign. Let q1 be positive and q2 be negative. The force of attraction is given by:F = (1/4πε) x (q1q2/r²)Therefore,F = (1/4πε) x [(q1 - q2)²/r²]0.300 = (1/4πε) x [(q1 - (-q1))²/(0.567)²]q1 = (0.300 x 4πε x (0.567)²)¹/² = 1.86 x 10⁻⁶ Cq2 = -q1 = -1.86 x 10⁻⁶ C. Thus, the charge on each particle in both cases is 4.00 μC and -1.86 x 10⁻⁶ C, respectively.
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Four identical railway trucks, each of mass m, were coupled together and are at rest on a smooth horizontal track. A fifth truck of mass m and moving at 5.00 m/s collides and couples with the stationary trucks. What is the speed of the trucks after the impact?
The velocity of the trucks after the collision is 5/9 m/s.
The given problem involves an elastic collision between a moving body and a stationary one. After the impact, the two bodies stick together. We have to find out the speed of the trucks after the impact.Four identical railway trucks, each of mass m, were coupled together and are at rest on a smooth horizontal track. A fifth truck of mass m and moving at 5.00 m/s collides and couples with the stationary trucks.
What is the speed of the trucks after the impact?The initial momentum of the moving truck is m * 5.00 = 5m.The initial momentum of the stationary trucks is 0. The total momentum before the impact is 5m.After the collision, the trucks move together as one system. Let us assume that the final velocity of the combined system is v. Since the trucks are identical, the center of mass of the system is at the center of the 5-truck system. Let us apply the law of conservation of momentum for the combined system.5m = (5m + 4m)v9m v = 5mv = 5/9 m/sTherefore, the velocity of the trucks after the collision is 5/9 m/s.
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A tennis ball is thrown vertically upwards at 29 m/sec from a height of 80 m above the ground. Determine the time it takes (in sec) for the tennis ball to hit the ground. (Use g = 9.8 m/s^2)
A tennis ball is thrown vertically upwards at 29 m/sec from a height of 80 m above the ground time cannot be negative, we discard t = 0 and conclude that it takes approximately 5.92 seconds for the tennis ball to hit the ground.
To determine the time it takes for the tennis ball to hit the ground, we can use the kinematic equation for vertical motion:
h = ut + (1/2)gt²
Where:
h is the initial height (80 m)
u is the initial velocity (29 m/s)
g is the acceleration due to gravity (-9.8 m/s²)
t is the time
We want to find the time it takes for the ball to hit the ground, which means the final height will be 0.
0 = (29)t + (1/2)(-9.8)t²
This equation represents a quadratic equation in terms of t. We can solve it by rearranging and factoring:
(1/2)(-9.8)t² + 29t = 0
Simplifying further:
-4.9t² + 29t = 0
Now, we can factor out t:
t(-4.9t + 29) = 0
This equation will be true when either t = 0 or -4.9t + 29 = 0.
From -4.9t + 29 = 0, we can solve for t:
-4.9t = -29
t = -29 / -4.9
t ≈ 5.92 s
Since time cannot be negative, we discard t = 0 and conclude that it takes approximately 5.92 seconds for the tennis ball to hit the ground.
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A solenoid of length 3.00 cm and radius 0.950 cm has 49 turns. If the wire of the solenoid has 1.35 amps of current, what is the magnitude of the magnetic field inside the solenoid? magnitude of the magnetic field: Ignoring the weak magnetic field outside the solenoid, find the magnetic energy density inside the solenoid. magnetic energy density:
The magnetic field inside a solenoid of length 3.00 cm and radius 0.950 cm with 49 turns and a wire that has 1.35 amps of current is 0.449 T.
The magnetic energy density inside the solenoid is 0.180 J/m³.
The magnetic field inside a solenoid can be given as; B = μ₀*n*I, Where;
B is the magnetic field, n is the number of turns per unit length, I is the currentμ₀ is the magnetic constant or permeability of free space.
We know that the length of the solenoid l = 3.00 cm and radius r = 0.950 cm, thus we can calculate the number of turns per unit length, n = N/l = 49/0.03 = 1633.33 turns/m
We know the current I is 1.35 ampsNow, using the formula,
B = μ₀*n*I
We can substitute the given values to obtain;
B = μ₀*n*I= 4π × 10⁻⁷ T*m/A × 1633.33 turns/m × 1.35
A= 0.449 T
Therefore, the magnitude of the magnetic field inside the solenoid is 0.449 T.
The magnetic energy density inside a magnetic field can be given as;u = (B²/2μ₀)We know the magnetic field inside the solenoid is 0.449 T, substituting this and the value of μ₀ = 4π × 10⁻⁷ T*m/A, we get;u = (B²/2μ₀) = (0.449²/2 × 4π × 10⁻⁷) = 0.180 J/m³
Therefore, the magnetic energy density inside the solenoid is 0.180 J/m³.
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Two identical 1.60 kg masses are pressed against opposite ends of a spring of force constant 1.65 N/cm , compressing the spring by 15.0 cm from its normal length.
Find the maximum speed of each mass when it has moved free of the spring on a smooth, horizontal lab table.
The maximum speed of each mass when it has moved free of the spring is approximately 0.431 m/s.
To find the maximum speed of each mass when it has moved free of the spring, we can use the principle of conservation of mechanical energy.
When the masses are pressed against the spring, the potential energy stored in the spring is given by the equation:
PE = (1/2)kx^2
Where PE is the potential energy, k is the force constant of the spring, and x is the compression or extension of the spring from its normal length.
In this case, the compression of the spring is 15.0 cm, or 0.15 m. The force constant is given as 1.65 N/cm, or 16.5 N/m. So the potential energy stored in the spring is:
PE = (1/2)(16.5 N/m)(0.15 m)^2 = 0.1485 J
According to the conservation of mechanical energy, this potential energy is converted into the kinetic energy of the masses when they are free of the spring.
The kinetic energy of an object is given by the equation:
KE = (1/2)mv^
Where KE is the kinetic energy, m is the mass, and v is the velocity of the object.
Since the masses are identical, each mass will have the same kinetic energy and maximum speed.
Setting the potential energy equal to the kinetic energy:
0.1485 J = (1/2)(1.60 kg)v^2
Solving for v:
v^2 = (2 * 0.1485 J) / (1.60 kg)
v^2 = 0.185625 J/kg
v = √(0.185625 J/kg) ≈ 0.431 m/s
Therefore, the maximum speed of each mass when it has moved free of the spring is approximately 0.431 m/s.
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