Answer: the answer given below
(a) Explanation: The impulse on an object is given by the change in momentum of the object. Before the collision, the bullet has momentum p1 = mv0 and the brick has momentum p2 = 0, since it is stationary. After the collision, the combined bullet-brick system has momentum p3.
Conservation of momentum requires that the total momentum before the collision is equal to the total momentum after the collision:
p1 + p2 = p3
mv0 + 0 = (m + M)V
where V is the velocity of the combined bullet-brick system after the collision. Solving for V, we get:
V = (mv0) / (m + M)
The impulse on the bullet during the collision is equal to the change in momentum of the bullet:
J_bullet = p3 - p1 = (m + M)V - mv0
Substituting the expression for V we found earlier:
J_bullet = (m + M)(mv0) / (m + M) - mv0 = 0
Therefore, the impulse on the bullet is zero during the collision.
On the other hand, the impulse on the brick during the collision is:
J_brick = p3 - p2 = (m + M)V - 0 = (m + M)(mv0) / (m + M) = mv0
Therefore, the magnitude of the impulse acting on the brick is equal to the initial momentum of the bullet, mv0, and it is in the same direction as the initial velocity of the bullet.
In summary, during the collision of the bullet and the brick, the impulse acting on the bullet is zero, while the impulse acting on the brick is mv0 in the direction of the initial velocity of the bullet.
(b) We can use the principle of conservation of momentum to solve for the velocity of the brick-bullet combination just after the collision. The total momentum of the system (bullet, brick, and Earth) is conserved before and after the collision. Initially, only the bullet has momentum, which is given by p1 = m*v0, and the momentum of the brick and Earth is zero. After the collision, the bullet becomes embedded in the brick, and the combined system of the brick-bullet has momentum p2. Since the momentum of the Earth is negligible compared to that of the bullet and brick, we can treat the system as closed and apply conservation of momentum:
p1 = p2
m*v0 = (M + m)*v
where v is the velocity of the combined system just after the collision.
Solving for v, we get:
v = (m*v0) / (M + m)
Therefore, the magnitude of the velocity of the brick-bullet combination just after the collision is:
|v| = |(m*v0) / (M + m)|
The direction of the velocity is upward, as the system swings up after the collision due to the conservation of momentum.
(c) The initial kinetic energy of the system is the kinetic energy of the bullet just before the collision, which is given by:
KE1 = (1/2)mv0^2
The final kinetic energy of the system is the kinetic energy of the combined brick-bullet system just after the collision, which is given by:
KE2 = (1/2)*(M + m)*v^2
Substituting the expression we found for v:
KE2 = (1/2)(M + m)[(mv0) / (M + m)]^2
KE2 = (1/2)(m*v0^2) / (1 + M/m)
The ratio of the final kinetic energy to the initial kinetic energy is:
KE2 / KE1 = [(1/2)(mv0^2) / (1 + M/m)] / [(1/2)mv0^2]
KE2 / KE1 = 1 / (1 + M/m)
Therefore, the ratio of the final kinetic energy of the brick-bullet combination immediately after the collision to the initial kinetic energy of the brick-bullet combination is:
KE2 / KE1 = 1 / (1 + M/m)
(d)To determine the maximum vertical position reached by the brick-bullet combination, we can use conservation of energy, assuming there is no energy loss due to friction or other dissipative forces. At the maximum height, the kinetic energy of the system is zero, and all the initial kinetic energy has been converted to potential energy due to the height above the initial position.
The initial total energy of the system is the sum of the initial kinetic energy of the bullet and the gravitational potential energy of the brick:
E1 = (1/2)mv0^2 + Mgh1
where h1 is the initial height of the brick above the ground, and g is the acceleration due to gravity.
At the maximum height, the final total energy of the system is the potential energy due to the height above the ground:
E2 = (M + m)gh2
where h2 is the maximum height reached by the brick-bullet combination above the initial position.
Since there is no energy loss, we can set the initial energy equal to the final energy:
E1 = E2
Substituting the expressions for E1 and E2 and solving for h2, we get:
(M + m)gh2 = (1/2)mv0^2 + Mgh1
h2 = [(1/2)mv0^2 + Mgh1] / [(M + m)*g]
Simplifying, we get:
h2 = (1/2)v0^2 / g + h1(M/m) / (1 + M/m)
Therefore, the maximum vertical position above the initial position reached by the brick-bullet combination is:
h2 = (1/2)v0^2 / g + h1(M/m) / (1 + M/m)
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the resistance between the two ends must remain the same, so what diameter must be chosen for the new wire?
T diameter of the new wire must be 0.1572 m in order to maintain the same resistance between the two ends.
To determine the diameter of the new wire required to maintain the same resistance, we can use the equation
R = ρL/A,
where R is the resistance, ρ is the resistivity of the material, L is the length, and A is the cross-sectional area of the wire.
Since we know that the resistance must remain the same, we can rearrange the equation to solve for A:
A = ρL/R.
Plugging in the given values for resistivity, length, and resistance, we can calculate the required cross-sectional area of the wire:
A = ρL/R = (0.0005 Ω⋅m)(5 m)/(5 Ω) = 0.0025 m^2.
Since the cross-sectional area of the wire is circular, we can use the equation for the area of a circle A = πr^2 to solve for the radius r, and thus the diameter d of the new wire:
r = sqrt(A/π) = sqrt(0.0025 m^2/π) = 0.0786 m
d = 2r = 2 x 0.0786 m = 0.1572 m
Therefore, the diameter of the new wire must be 0.1572 m in order to maintain the same resistance between the two ends.
When the resistance between the two ends must remain the same, the diameter chosen for the new wire is directly proportional to the length of the wire. According to Ohm's law, resistance is directly proportional to length and inversely proportional to the cross-sectional area of the wire. Therefore, if the length of the wire doubles, the resistance doubles, and if the area of the wire doubles, the resistance is halved.This means that when the resistance between the two ends must remain the same, the diameter of the new wire must be such that the cross-sectional area of the wire is proportional to the length of the wire. In other words, if the new wire is half the length of the original wire, its diameter should be twice that of the original wire, and so on.
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if the protons are both released from rest at the closer distance in part a, how fast are they moving when they reach their original separation?
v_max = √(2kq1q2 / (md))
To determine the speed of the protons when they reach their original separation after being released from rest at the closer distance, we can use the principle of conservation of mechanical energy.
According to the given problem, the protons are initially at rest at a closer distance. This means they have zero initial kinetic energy (KE) and only potential energy (PE) due to their separation.
As they move towards each other under the influence of electrostatic force, their potential energy is converted into kinetic energy.
At the original separation, the protons would have reached their maximum kinetic energy, as all of the potential energy would have been converted into kinetic energy. Let's denote this maximum kinetic energy as KE_max.
The total mechanical energy (E) of the protons, which is the sum of their kinetic energy and potential energy, remains constant throughout their motion. So we have:
E = KE + PE
At the original separation, KE = KE_max and PE = 0, as the protons have zero potential energy at that point.
So we can write:
E = KE_max + 0
E = KE_max
Now, let's denote the speed of the protons at the original separation as v_max. We can use the formula for kinetic energy:
KE = 1/2 mv^2
where m is the mass of the proton and v is its speed. Substituting KE_max for E and v_max for v, we have:
KE_max = 1/2 m v_max^2
Since the protons have no initial kinetic energy, their total mechanical energy E is equal to their initial potential energy PE, which is given by the equation:
PE = kq1q2 / d
where k is the electrostatic constant, q1 and q2 are the charges of the protons, and d is their initial separation (closer distance in part a).
Now, if we equate the expressions for KE_max and PE, we get:
1/2 m v_max^2 = kq1q2 / d
Solving for v_max, we have:
v_max = √(2kq1q2 / (md))
where √ denotes the square root.
So, to find the speed of the protons when they reach their original separation, you would need to know the values of the electrostatic constant (k), the charges of the protons (q1 and q2), the mass of the proton (m), and the initial separation (d), and then plug these values into the equation above to calculate v_max.
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if a star is 11 pc away from us, will its apparent visual magnitude be higher or lower than its absolute visual magnitude? what if the star is 5 pc away?
If a star is 11 pc away from us, its apparent visual magnitude will be lower than its absolute visual magnitude. The star's apparent magnitude would be only 0.38 magnitudes lower than its absolute magnitude.
This is because the apparent magnitude of a star is affected by its distance from us. As the distance increases, the star appears dimmer, and its apparent magnitude decreases.
The distance modulus formula gives us a way to calculate the difference between the apparent and absolute magnitudes of a star:
Distance modulus = 5 * log(distance in parsecs) - 5
For a star that is 11 pc away, the distance modulus is,
Distance modulus = 5 * log(11) - 5 = 1.38
This means that the star's apparent magnitude will be 1.38 magnitudes lower than its absolute magnitude.
If the same star were only 5 pc away from us, the distance modulus would be,
Distance modulus = 5 * log(5) - 5 = 0.38
In this case, the star's apparent magnitude would be only 0.38 magnitudes lower than its absolute magnitude. This means that the star would appear brighter and have a higher apparent magnitude when it is closer to us.
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after conducting a series of experiments, a physicist concluded that the pressure around an object placed in a moving fluid is given by where is the square of the ratio of the speed of the fluid to the speed of sound, is a positive constant, and is a positive integer greater than 1. use linear approximation to prove that the pressure is approximately for small values of _____
The pressure around an object placed in a moving fluid can be proved using a point-slope form of a line.
Explanation:
Linear approximation is the process of approximating a function with a linear function that is tangent to the curve at a particular point. The formula provided in the question is as follows: Where is the square of the ratio of the speed of the fluid to the speed of sound, is a positive constant, and is a positive integer greater than 1. We are asked to use linear approximation to prove that the pressure is approximately for small values of x. To use linear approximation, we need to take the derivative of the function and evaluate it at the point we are approximating. This will give us the slope of the tangent line at that point.
The derivative of the function is: Now we need to evaluate the derivative at the point x = 0. This will give us the slope of the tangent line at that point. Plugging in x = 0, we get: the slope of the tangent line at x = 0 is 2c. Now we can use the point-slope form of a line to find the equation of the tangent line: Plugging in x = 0 and simplifying, we get the linear approximation of the function for small values of x.
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A dog can hear sounds in the range from 15
to 50,000 Hz.
What wavelength corresponds to the lower
cut-off point of the sounds at 20◦C where the
sound speed is 344 m/s?
Answer in units of m.
Explanation:
Speed of sound is 344
The frequency corresponding to the lower cut-off point is the lowest frequency which his 15Hz
F=15Hz
The relationship between the wavelength, speed and frequency is given as
v=fλ
Then,
λ=v/f
λ=v/f
λ=344/15
λ=22.93m
What is the mass of a student who weighs 524 newton
Mass of the student is approximately 53.47 kilograms.
The mass of a student who weighs 524 Newton can be calculated using the formula: Weight = Mass x Gravity
Assuming the acceleration due to gravity is approximately 9.8 meters per second squared on the Earth's surface : Mass = Weight / Gravity
Substituting the given weight of 524 Newton, we get:
Mass = 524 N / 9.8 m/s^2 ≈ 53.47 kg
The mass of the student is approximately 53.47 kilograms. It is important to note that mass is a measure of the amount of matter in an object and is different from weight, which is the force exerted on an object due to gravity.
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you have been hired to design a spring-launched roller coaster that will carry two passengers per car. the car goes up a 10-m -high hill, then descends 15 m to the track's lowest point. you've determined that the spring can be compressed a maximum of 2.2 m and that a loaded car will have a maximum mass of 440 kg . for safety reasons, the spring constant should be 11 % larger than the minimum needed for the car to just make it over the top.
In order to design a spring-launched roller coaster that will carry two passengers per car, a spring constant of approximately 4255.78 N/m is needed for the roller coaster to be safe.
Several factors must be taken into consideration. The car must go up a 10-m-high hill and then descend 15 m to the track's lowest point. The maximum amount the spring can be compressed is 2.2 m, and a loaded car will have a maximum mass of 440 kg. Additionally, for safety reasons, the spring constant should be 11% larger than the minimum needed for the car to just make it over the top.
To determine the spring constant needed for the roller coaster, we can use the following formula:
U = (1/2)kx²where U is the potential energy of the spring, k is the spring constant, and x is the distance the spring is compressed. To find the minimum spring constant needed for the car to just make it over the top of the hill, we can set the potential energy of the spring equal to the potential energy of the car at the top of the hill:
U = mgh, where m is the mass of the car, g is the acceleration due to gravity, and h is the height of the hill.
U = (1/2)kx²mgh
= (1/2)kx²k = 2mgh/x²
Plugging in the given values, we get: k = 2(440 kg)(9.81 m/s²)(10 m)/(2.2 m)²k ≈ 3831.64 N/m. To find the spring constant needed for safety reasons, we can multiply the minimum spring constant by 1.11:k' = 1.11k' ≈ 4255.78 N/m
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a girl at a skate park starts at rest, at the top of a 33 meter-high hill. how fast is she traveling when she reaches the top of the second hill, only 5 meters high? (assume no friction loss.)
She traveling when she reaches the top of the second hill, only 5 meters high is 17.71m/s fast.
Given:
u=0 at A
h_1=27m
v=? at B
h2=11m
Apply law of conservation of energy; at A & B;
[tex]1 / 2mu^2 + mgh_1 = 1 / 2 mv^2 + mgh_2\\mgh_1 = 1/2mv^2 + mgh_2\\2gh_1 = v^2 + 2gh^2\\v^2 = 2g(h_1 - h_2)\\v=\sqrt{2*9.8[27-11]}\\[/tex]
v = 17.71m/s
Friction is a fundamental phenomenon that arises whenever there is contact between two surfaces, and it is an essential aspect of our everyday lives. The origin of friction lies in the intermolecular forces that exist between the atoms and molecules that make up the surfaces in contact.
When two surfaces come into contact, these intermolecular forces create a resistance to the relative motion of the surfaces. This resistance manifests as a force that opposes the direction of motion, and it is known as friction. Friction can be both beneficial and detrimental. On one hand, it allows us to walk, drive, and manipulate objects. On the other hand, it can cause wear and tear on machinery and create unwanted heat, which can be wasteful and even dangerous.
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a ball is dropped from a distance 5 m above the ground, and it hits the ground with a certain speed. if the same ball is dropped from a distance 10 m above the ground, its final speed will be
The final speed of the ball dropped from a distance of 10 meters will be 49 m/s.
The final speed of the ball dropped from a distance of 10 meters will be higher than the final speed of the ball dropped from a distance of 5 meters. This is because of the effect of gravity on the ball.
As the ball falls, gravity will pull it toward the ground, giving it a greater speed as it falls further. This increase in speed is known as the "acceleration due to gravity."
When the ball is dropped from 10 meters, the ball will fall faster because of the increased distance it has to travel, allowing gravity to pull it down more quickly.
By the time it reaches the ground, it will have reached a higher velocity.
The equation for this acceleration due to gravity is:
Vf = Vi + g × t
Where Vf is the final speed, Vi is the initial speed, g is the acceleration due to gravity and t is the time.
Therefore, in order to calculate the final speed of the ball dropped from 10 meters, we can use this equation. Assuming the initial speed of the ball is zero and the acceleration due to gravity is 9.8 m/s2, we get:
Vf = 0 + 9.8 × (10/2)
Vf = 49 m/s
So, the final speed of the ball dropped from a distance of 10 meters will be 49 m/s.
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the cantilevered beam is made of a36 steel and is subjected to the loading shown. determine the displacement at b using the method of superposition. for a36 steel beam, the moment of inertia i
Thus using method of superposition, the total displacement is 0.0276.
A36 steel beam is used Cantilever beam is loaded. The moment of inertia is I. For A36 steel beam, I = 6667 in4 (approx.)As per the method of superposition, the total displacement of the beam at point B is given as follows:δtotal = δP + δWWhere,δP is the displacement of point B due to the point loadδW is the displacement of point B due to the uniformly distributed load.
Considering point load,P = 1500 lb. Distance of the point load from point B = 5 ft. Thus, the moment at point B due to point load can be calculated as follows: MBP = PL = 1500 × 5 = 7500 lb-ft. Similarly, considering uniformly distributed load,W = 200 lb/ft. Thus, the moment at point B due to uniformly distributed load can be calculated as follows:Mbw = (wL2)/12Where,L is the length of the beam= 10 ft
Therefore, Mbw = (200 × 102)/12 = 1667 lb-ft (approx.)Thus, total moment at point B,M = MBP + MBW= 7500 + 1667= 9167 lb-ft. Thus, using the formula for deflection of cantilever beam,δP = (PbL2)/(2EI) = (1500 × 52)/(2 × 29 × 106 × 6667) = 0.0026 inδW = (WbL3)/(3EI) = (200 × 5103)/(3 × 29 × 106 × 6667) = 0.024 in
Therefore, the displacement at point B is 0.0276 in.
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the average distance from mars to the sun is 1.524 astronomical units (1.524 au) and the eccentricity of mars' orbit is 0.0935. what is the distance from the mars to the sun in astronomical units when mars is at perihelion?
The distance from Mars to the sun in astronomical units when Mars is at perihelion is 1.381 astronomical units.
What is perihelion?Perihelion is the point in the orbit of a planet or other celestial body where it is closest to the sun. This concept applies to planets in the Solar System, such as Mars. Kepler's laws of planetary motion explain how planets move around the sun in elliptical orbits, with the sun at one of the two foci of the ellipse.
The distance between Mars and the sun varies since Mars has an elliptical orbit. Mars' average distance from the sun is 1.524 astronomical units. The distance from Mars to the sun in astronomical units when Mars is at perihelion is given as 1.381 astronomical units. The eccentricity of Mars' orbit is also given as 0.0935. Eccentricity is the degree of elongation of an elliptical orbit, with a value ranging from 0 to 1. An orbit is circular when its eccentricity is 0, whereas it is more elongated as the value approaches 1.
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Describe the shape of the graph, and explain what it says about the relationship between height and gravitational potential energy.
A doubling of the height will result in a doubling of the gravitational potential energy since the gravitational potential energy of an item is precisely proportional to its height above the zero point.
How do height and gravitational potential relate to one other?The mass and height of an item affect the gravitational potential energy. V = -GM/r is the formula for gravitational potential. U = mgh is the formula for gravitational potential energy.
What connection exists between height and the acceleration of gravity?This is the acceleration brought on by gravity while you are above the earth's surface. Based on the aforementioned calculation, we may conclude that as an object's height increases, the value of g falls until it is zero.
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The river is an archetypal setting that is used in both The Aeneid and Hades: Lord of the Dead. Explain the symbolic importance of the river archetype and how it relates to the events described in the selections
The river archetype is a not unusual and powerful symbol in literature that represents the glide of time and the adventure of life. In both the texts, the river serves as a symbolic place that is deeply linked to the events defined within the choices.
The river archetype is a powerful symbol in many cultures and mythologies, representing the flow of life and the journey of the human soul. The river is often seen as a source of vitality and renewal, as well as a path toward transformation and self-discovery.
In literature and mythology, the river often serves as a metaphor for the passage of time and the inevitability of change. The river can be calm and gentle, or wild and dangerous, reflecting the ups and downs of life and the challenges we face on our journey. The river archetype can also represent the collective unconscious, the deep wellspring of human experience and wisdom that connects us all.
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calculate the resultant velocity of an airplane that normally flies at 250 km/h if it encounters a 50-km/h tailwind. answer in units of km/h.
The resultant velocity of an airplane that normally flies at 250 km/h with a 50-km/h tailwind is 300 km/h.
This is because the velocity of the tailwind adds to the airplane's velocity, creating a total velocity of 300 km/h.
Velocity is the speed at which something moves in a particular direction. It can increase or decrease depending on what it encounters on its path.
To calculate the resultant velocity, use the equation:
Resultant Velocity = (Initial Velocity + Wind Velocity)
Resultant Velocity = (250 km/h + 50 km/h)
Resultant Velocity = 300 km/h
Therefore, the resultant velocity of an airplane when it encounters a 50 km/h tailwind is 300 km/h.
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a diver jumps off the diving board. he pushes himself downward at a rate of 2 m/s. gravity increases his downward velocity to 6 m/s when he hits tthe water 1.5 seconds later. what is his acceleration?
The diver's acceleration is 2.67 m/s^2.
We can use the formula for acceleration:
a = (vf - vi) / t
where a is acceleration, vf is final velocity, vi is initial velocity, and t is time.
In this problem, the initial velocity (vi) is 2 m/s downward, the final velocity (vf) is 6 m/s downward, and the time (t) is 1.5 seconds.
Plugging in these values, we get:
a = (6 m/s - 2 m/s) / 1.5 s
a = 4 m/s / 1.5 s
a = 2.67 m/s^2
As a result, the acceleration of the diver is 2.67 m/s^2.
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a 0.170-kg baseball traveling 30.0 m/s strikes the catcher's mitt, which, in bringing the ball to rest, recoils backward 15.0 cm . what was the magnitude of the average force applied by the ball on the glove?
The magnitude of the average force applied by the ball on the glove is 34 N.
The magnitude of the average force applied by the ball on the glove.
This can be done by using the equation for force, F = ma, where F is the force, m is the mass of the object, and a is the acceleration of the object.
The mass of the ball is 0.170 kg, and the acceleration is determined by the change in velocity of the ball and the distance the glove recoils, 15 cm, or 0.15 m.
Therefore, the acceleration of the ball is a = (30.0 m/s - 0 m/s)/(0.15 m) = 200 m/s^2.
Since we have the mass and the acceleration, we can calculate the force with the equation above. F = (0.170 kg)(200 m/s^2) = 34 N. Therefore, the magnitude of the average force applied by the ball on the glove is 34 N.
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a firefighter of mass 30 kg slides down a vertical pole with an acceleration of 5m/s^2. what is the net force acting on him?
The net force acting on the firefighter is 30 kg × 9.8 m/s2 + 4.8 m/s2 = 148 N.
The net force acting on the firefighter of mass 30 kg is the sum of all forces acting on him,
which is equal to the mass of the firefighter multiplied by the acceleration due to gravity plus the frictional force between the pole and the firefighter.
The net force on the firefighter can be calculated using the following equation:
Net force = mass × acceleration due to gravity + frictional force
Net force = 30 kg × 9.8 m/s2 + frictional force
Since the firefighter is accelerating at 5 m/s2, subtract the frictional force from the acceleration due to gravity (9.8 m/s2):
Frictional force = 9.8 m/s2 - 5 m/s2 = 4.8 m/s2
Therefore, the net force acting on the firefighter is 30 kg × 9.8 m/s2 + 4.8 m/s2 = 148 N.
This net force is made up of the gravitational force of 30 kg × 9.8 m/s2 and the frictional force of 4.8 m/s2.
This frictional force allows the firefighter to move down the pole at an accelerating rate of 5 m/s2. Without this frictional force, the firefighter would not move.
The net force acting on the firefighter is 148 N, which is equal to the mass of the firefighter multiplied by the acceleration due to gravity plus the frictional force between the pole and the firefighter.
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how much work was needed by an external force to assemble the three charges into the configuration above, assuming they started infinitely far away from each other?
The work was needed by an external force to assemble the three charges into the configuration are: q1= -4µC, q2 = +2 µC, and q3 = +6 µC are located at A, B, and C respectively. The distance between AB is 3m and the distance between BC is 4m.
The configuration is shown above: assuming they started infinitely far away from each other, External force is the force exerted by something outside of the system. It is a force from an external source. This work of assembling the three charges is performed by the external force. To calculate this, consider the configuration shown above.The work done by the external force is the potential energy of the charges.
The work is given byW = PEA potential energy of two charges is given by PE = kq1q2/r Where k = Coulomb’s constant = 9 x 10^9 Nm²/C²q1 and q2 = charges of two charges in Coulombsr = distance between the charges in meters as three charges are involved, calculate potential energy for each pair of charges and then add them.
W1 = Potential energy between charges A and B = k q1 q2 / r1W2 = Potential energy between charges B and C = k q2 q3 / r2W3 = Potential energy between charges A and C = k q1 q3 / r3Total potential energy W = W1 + W2 + W3 = kq1q2/r1 + kq2q3/r2 + kq1q3/r3 = 9 x 10^9 x [-4 x 10^-6 x 2 x 10^-6/3 + 2 x 10^-6 x 6 x 10^-6/4 + -4 x 10^-6 x 6 x 10^-6/5]W = -3.168 x 10^-5 Joule.
The negative sign indicates the work done by an external force to assemble the three charges into the configuration above, assuming they started infinitely far away from each other. Thus, the required work is 3.168 x 10^-5 Joule.
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A concave lens is shown here. According to the model, a lens disperses rays after passing through it. Which item below most likely uses a concave lens to perform its typical function?
The item that most likely uses a concave lens to perform its typical function is a concave lens .
What is a concave lens?A concave lens is a lens that is thinner at the center and thicker at the edges, causing it to diverge parallel rays of light.
How is a concave lens used in a camera?A concave lens is used in a camera to allow the photographer to adjust the focus of the camera by moving the lens closer to or farther away from the film or sensor. When the lens is moved closer to the film or sensor, it increases the distance between the lens and the object being photographed, causing the image to appear larger and bringing objects into focus that were previously blurry.
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determine the limit on the series resistance so the energy remaining after one hour is at least 85 percent of the initial energy.
The limit on the series resistance so that the energy remaining after one hour is at least 85 percent of the initial energy, is initial energy into 85% by the voltage.
Ohm's Law states that the current in a circuit is directly proportional to the voltage and inversely proportional to the resistance.
Therefore, the total resistance in a circuit can be calculated using the formula: R = V/I
The energy remaining after one hour must be at least 85 percent of the initial energy, we can calculate the resistance by rearranging the formula.
The total resistance can be determined by multiplying the initial energy by 85 percent and dividing it by the voltage. Thus, the limit on the series resistance is [tex]R = (Initial Energy *0.85) / V[/tex].
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when a honeybee flies through the air, it develops a charge of 20 pc . part a how many electrons did it lose in the process of acquiring this charge?
When a honeybee flies through the air, it acquires a charge of +20 pC. Part A: It loses 4 electrons in the process.
at what distance from a converging mirror with a 26 cm focal length should an object be placed so that its image is the same distance from the mirror as the object?
At what distance from a converging mirror with a 26 cm focal length should an object be placed so that its image is the same distance from the object should be placed 52 cm away from the mirror.
The image of the object is formed when light rays from the object intersect at a single point. The distance between this point and the mirror is the same as the distance between the mirror and the object.
This distance is known as the focal length of the mirror.The image is the same distance away from the mirror as the object. In this situation, the mirror is a converging mirror because it has a focal length.
To determine the position of the object, we can use the mirror formula.
1/f = 1/u + 1/v
where f is the focal length of the mirror,
u is the distance of the object from the mirror, and
v is the distance of the image from the mirror.
When u = v, we can substitute u with v in the equation to get
2/f = 1/uu = 2f
To determine the distance from the mirror to the object, we may now substitute the values of f and u.
The distance is equal to twice the focal length of the mirror.
Distance of object = 2(26 cm)Distance of object
= 52 cm.
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the sound level measured in a room by a person watching a movie on a home theater system varies from 60 db during a quiet part to 90 db during a loud part. approximately how many times louder is the latter sound?
The loud part is approximately 1000 times louder than the quiet part. The sound level measured in a room by a person watching a movie on a home theater system varies from 60 db during a quiet part to 90 db during a loud part.
To calculate approximately how many times louder the latter sound is, we can use the formula: Decibels = 10 log (I/I0) Where I is the sound intensity and I0 is the reference intensity ([tex]10^{-12} W/m^2[/tex]). We know that the sound level at the quiet part is 60 dB and the sound level at the loud part is 90 dB.
So, using the formula above, we can calculate the intensity ratio as follows: Intensity ratio = I_loud/I_quiet= [tex]10^{(90/10)}[/tex]/ [tex]10^{(60/10)}[/tex]= [tex]10^9[/tex]/[tex]10^6[/tex]= 1000. The intensity ratio of the loud part to the quiet part is 1000. This means that the loud part is approximately 1000 times louder than the quiet part. The answer is 1000 times louder than the quiet part.
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Force exerted by a person or an object is called an ______________________ force.
The force exerted by a person or an object is called an applied force.
What is applied force?When a person or an object exerts force on another object, this force is called an applied force. Applied forces can be exerted in many different ways and can have a variety of effects on the objects they act upon. For example, a person might apply force to push a box across the floor, or an object might apply force to hold a book against a table.
Applied forces can be characterized by their direction, magnitude, and point of application. The direction of an applied force is the direction in which the force is being exerted (such as left, right, up, or down). The magnitude of an applied force is the amount of force being exerted (measured in newtons). The point of application of an applied force is the point at which the force is being exerted on the object.
It is important to note that applied forces can only be exerted on other objects - they cannot be exerted on the object that is doing the exerting. For example, if you push a box across the floor, you are applying a force to the box, not to yourself. This is because forces always occur in pairs - for every action, there is an equal and opposite reaction.
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please help me!!!!! (i beg)
Answer:
A
Explanation:
This is based on the theory by J. J. THOMPSON
a ball with a mass of 0.50kg and a speed of 6 m/s collides perpendicularly with a wall and bounces off with a speed of 4 m/s in the opposite direction. what is the magnitude of the impulse acting on the ball
(C) 5 Ns and Usage J = p are the appropriate choices. J = mvf-mvi J = (0.5)(– 4) – (0.5)(6). (6). A massed item changes its velocity in response to a pulling or pushing action.
A body can change its condition of rest or motion by the application of force, which is an external agent. It is directed and has a volume.
The direction of a body or object's motion is defined by its velocity. Most of the time, speed is a multidimensional number. In its purest form, velocity refers to a vector quantity. The pace at which distance changes is what it is. It is the pace at which displacement is changing.
What are referred to as velocity and speed?
Velocity is the pace and directions of an item's motion, whereas speed is indeed the time rate when an object is travelling along a route.
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" Complete question"
A ball with a mass of 0.50kg and a speed of 6 m/s collides perpendicularly with a wall and bounces off with a speed of 4m/s in the opposite direction. What is the magnitude of the impulse acting on the ball?
(A) 13 J
(B) 1Ns
(C) 5Ns
(D) 2m/s
(E) 10m/s
Help, I cant do it by myself and I really need this done. Please.
Part One
Text Version
Image shows a lake, a factory, a cloud in the sky, a cow, dead organisms, a tree, and the sun. An arrow from the sun to the tree is labeled A. An arrow from the sky to the tree is labeled B. The sky is labeled C above the cloud. The letter D is in the air and an arrow points from it down to dead organisms. An arrow points from dead organisms to the ground labeled E. An arrow points from the cow into to the sky labeled F. An arrow points from the factory to the sky labeled G. An arrow from the sky to the lake is labeled H above the lake.
Using the diagram above, match the description to the corresponding location in the carbon cycle model. Provide the letter only.
Carbon dioxide is converted to sugar used for food.
Location:
Carbon trapped in fossil fuels is converted to carbon dioxide.
Location:
Organic carbon is converted to fossil fuels.
Location:
Carbon dioxide is converted to carbonates.
Location:
Sugar is broken down and converted to carbon dioxide.
Location:
Part Two
Text Version
Images shows a lake labeled carbonates in water, a cow labeled animal respiration, a tree labeled photosynthesis, a factory labeled factory emissions, the sun labeled sunlight, a cloud labeled carbon dioxide in atmosphere, another tree labeled plant respiration, an arrow from organic carbon to dead organism, and fossils and fossil fuels. Arrows are labeled as follows: A from the sunlight to photosynthesis, B from carbon dioxide in atmosphere to photosynthesis, C from factory emissions to carbon dioxide in atmosphere, D from carbon dioxide in atmosphere to carbonates in water, E from dead organisms to fossils and fossil fuels, and F from plant respiration to the sky.
Using the diagram above, answer the following questions:
True or False. The arrow labeled C represents a transfer of chemical energy to mechanical energy. Explain why this is true or false.
True or False. The arrow labeled A represents a transfer of solar energy to chemical energy. Explain why this is true or false.
Which arrow or arrows represent a release of carbon dioxide? What process is occurring at the arrow(s) you selected?
Which arrow or arrows indicate a process that cycles carbon from living or nonliving organisms? Describe the process or processes you selected.
Which arrow or arrows represent reactions that demonstrate a conservation of mass and energy? Explain your answer.
Answer:
Part One:
Location: A - The arrow from the sun to the tree represents photosynthesis, where carbon dioxide is converted to sugar used for food.
Answer: A
Location: G - The arrow from the factory to the sky represents the release of carbon dioxide from factory emissions, which contributes to the conversion of carbon trapped in fossil fuels to carbon dioxide.
Answer: G
Location: E - The arrow from dead organisms to the ground represents the process where organic carbon is converted to fossil fuels over a long period of time.
Answer: E
Location: D - The arrow from the air to dead organisms represents the conversion of carbon dioxide to carbonates, which can be deposited in the ocean and form rocks over millions of years.
Answer: D
Location: F - The arrow from the cow to the sky represents animal respiration, where sugar is broken down and converted to carbon dioxide.
Answer: F
Part Two:
True or False. The arrow labeled C represents a transfer of chemical energy to mechanical energy. Explain why this is true or false.
False. The arrow labeled C represents the transfer of chemical energy (carbon dioxide) from the factory emissions to the atmosphere. There is no mechanical energy involved in this process.
True or False. The arrow labeled A represents a transfer of solar energy to chemical energy. Explain why this is true or false.
True. The arrow labeled A represents photosynthesis, where solar energy is used to convert carbon dioxide into chemical energy in the form of sugar.
Which arrow or arrows represent a release of carbon dioxide? What process is occurring at the arrow(s) you selected?
Arrows C and F represent a release of carbon dioxide. Arrow C represents the release of carbon dioxide from factory emissions, while arrow F represents animal respiration where sugar is broken down to release carbon dioxide.
Which arrow or arrows indicate a process that cycles carbon from living or nonliving organisms? Describe the process or processes you selected.
Arrows B, D, and E indicate processes that cycle carbon from living or nonliving organisms. Arrow B represents photosynthesis where carbon dioxide is taken up by plants, arrow D represents the conversion of carbon dioxide to carbonates which can be deposited in the ocean and form rocks over millions of years, and arrow E represents the conversion of dead organisms into fossil fuels over a long period of time.
Which arrow or arrows represent reactions that demonstrate a conservation of mass and energy? Explain your answer.
All arrows in the diagram demonstrate the conservation of mass and energy. The carbon cycle is a closed system, meaning that the total mass of carbon in the cycle remains constant over time. Energy is also conserved as it is converted from one form to another throughout the cycle.
a parallel-plate capacitor has a plate area of 12.9 cm2 and a capacitance of 9 pf . what is the plate separation? the value of the permittivity of a vacuum is
Answer:For parallel plate capacitors, the capacitance (dependent on its geometry) is given by the formula C=ϵ⋅Ad C = ϵ ⋅ A d , where C is the value of the capacitance, A is the area of each plate, d is the distance between the plates, and ϵ is the permittivity of the material between the plates of the parallel capacitor.
in their most basic sense, waves are . they are generally classified by the disturbing force that causes the wave and the restoring force that returns the water to normal once it has passed. for example, the disturbing force for wind waves is usually and the restoring force is .
Answer:
The restoring force is Gravity.
Explanation:
In their most basic sense, waves are disturbances that travel through a medium, usually without the permanent displacement of the particles of the medium.
They are generally classified by the disturbing force that causes the wave and the restoring force that returns the water to normal once it has passed.
For example, the disturbing force for wind waves is usually wind and the restoring force is gravity.
Wind provides energy to the water, creating ripples and waves that travel across the surface of the water.
Gravity then acts to restore the surface of the water to its original state, pulling the water back down into the trough of the wave.
As the wave moves through the water, the water itself does not travel with the wave but instead moves in a circular motion, with the circular motion decreasing in size as it moves away from the wave.
This motion of the water is known as an orbital motion, with water particles moving in a circular motion but not traveling with the wave itself.
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water flows with constant speed through a garden hose that goes up a step 20.0 cm high. if the water pressure is 143 kpa at the bottom of the step, what is its pressure at the top of the step?
The pressure at the top of the step is 339 kPa.
We can use the principle of conservation of energy to solve this problem. The total energy of the water at any point along the hose can be expressed as the sum of its potential energy and kinetic energy. Since the water flows with constant speed, its kinetic energy remains constant throughout the hose. Thus, any change in energy must be due to a change in potential energy.
At the bottom of the step, the pressure is given as P1 = 143 kPa. Let's assume that the cross-sectional area of the hose remains constant throughout, so that the volume of water flowing per unit time remains constant as well. Let V be the volume of water flowing per unit time, and let A be the cross-sectional area of the hose. Then, the speed of the water is given by v = V/A.
As the water flows up the step, it gains potential energy due to its increase in height. The increase in potential energy per unit volume of water is given by the product of the height difference and the density of water (ρ = 1000 kg/m³) multiplied by the gravitational acceleration (g = 9.8 m/s²): ΔU/V = ρgh.
Let P2 be the pressure at the top of the step, and let h = 0.2 m be the height of the step. Then, the pressure difference between the top and bottom of the step is given by ΔP = P2 - P1, and the change in potential energy per unit volume of water is ΔU/V = ρgh. Therefore, using the principle of conservation of energy, we have:
1/2 ρv² + P1 = 1/2 ρv² + P2 + ρgh
Simplifying and solving for P2, we get:
P2 = P1 + ρgh
Plugging in the given values, we get:
P2 = 143 kPa + (1000 kg/m³)(9.8 m/s²)(0.2 m) = 143 kPa + 196 kPa = 339 kPa
Therefore, the pressure is 339 kPa.
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