Identify the forces acting on the puck.
Check all that apply. © A. Static friction J, © B. Tension O C. Thrust Filrust
C D. Normal force O e. Weight.

Answers

Answer 1

When a hockey puck slides on rough ice after a slapshot, there are several forces that act on it. These forces include weight, normal force, thrust force, and friction forces.


Weight: The weight of the puck is a force that is caused by gravity acting on the puck. This force is always directed downward.

Normal force: The normal force is the force that is perpendicular to the surface on which the puck is sliding. This force is caused by the resistance of the surface and is always directed upwards.

Thrust force: The thrust force is the force that is applied to the puck by the player when they slap the puck. This force is always directed in the direction that the player wants the puck to go.

Friction forces: Friction forces are forces that resist motion and they are caused by the roughness of the ice.

There are two types of friction forces that act on the puck: static friction and kinetic friction.

Static friction: Static friction is the friction force that keeps the puck from moving when it is at rest. When the puck is first hit by the player, there is static friction between the puck and the ice that prevents the puck from moving until the thrust force overcomes it.

Kinetic friction: Kinetic friction is the friction force that acts on the puck when it is sliding on the ice. This force is always directed in the opposite direction to the motion of the puck.

The question should be:

When a hockey puck is sliding on rough ice after being hit with a slapshot, identify the forces that play on it.

A. Static friction J, B. Tension O C. Thrust FilrustC D. Normal force O e. Weight.

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Related Questions

Question 43 1 pts An aluminum calorimeter of mass 52 g, has 172 g water, both at a temperature of 20.9°C. A 159-g piece of Copper originally kept in boiling water (T= 100°C) is transferred to the calorimeter. Calculate the final equilibrium temperature of the mixture in °C. Specific Heats: Al = 900 J/kg, water =4186 J/g, Cu = 387 J/kg.

Answers

The final equilibrium temperature of the mixture is approximately 22.8°C when the copper piece is transferred to the aluminum calorimeter containing water.

To determine the final equilibrium temperature of the mixture, we can use the principle of energy conservation. The heat gained by the cooler objects (water and aluminum calorimeter) should be equal to the heat lost by the hotter object (copper piece).

First, let's calculate the heat gained by the water and calorimeter. The specific heat capacity of water is 4186 J/kg°C, and the mass of water is 172 g. The specific heat capacity of aluminum is 900 J/kg°C, and the mass of the calorimeter is 52 g. The initial temperature of both the water and calorimeter is 20.9°C. We can calculate the heat gained as follows:

Heat gained by water and calorimeter = (mass of water × specific heat capacity of water + mass of calorimeter × specific heat capacity of aluminum) × (final temperature - initial temperature)

Next, let's calculate the heat lost by the copper piece. The specific heat capacity of copper is 387 J/kg°C. The mass of the copper piece is 159 g, and its initial temperature is 100°C. We can calculate the heat lost as follows:

Heat lost by copper = mass of copper × specific heat capacity of copper × (initial temperature - final temperature)

Since the heat gained and heat lost should be equal, we can set up the following equation:

(mass of water × specific heat capacity of water + mass of calorimeter × specific heat capacity of aluminum) × (final temperature - initial temperature) = mass of copper × specific heat capacity of copper × (initial temperature - final temperature)

By solving this equation, we can find the final equilibrium temperature of the mixture. After performing the calculations, we find that the final equilibrium temperature is approximately 22.8°C.

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Assume you charge a comb by running it through your hair and then hold the comb next to a bar magnet. Do the electric and magnetic fields produced constitute an electromagnetic wave?(a) Yes they do, necessarily.(b) Yes they do because charged particles are moving inside the bar magnet.(c) They can, but only if the electric field of the comb and the magnetic field of the magnet are perpendicular.(d) They can, but only if both the comb and the magnet are moving. (e) They can, if either the comb or the magnet or both are accelerating.

Answers

The electric and magnetic fields produced by charging a comb and holding it next to a bar magnet do not necessarily constitute an electromagnetic wave.

Option (c) is correct

They can form an electromagnetic wave, but only if the electric field of the comb and the magnetic field of the magnet are perpendicular. The movement of charged particles inside the bar magnet, as mentioned in option (b), is not directly related to the formation of an electromagnetic wave.

Additionally, options (d) and (e) are not necessary conditions for the production of an electromagnetic wave. They can form an electromagnetic wave, but only if the electric field of the comb and the magnetic field of the magnet are perpendicular.

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1. The human eye detects (b) a) longitudinal waves b) transverse waves 2. The type of lens used to correct for being nearsighted. (a) a) concave lens b) convex lens 3. The primary colors of light are 4. Briefly explain why the sky appears blue during the day. 5. Matching: Place the following scientists - Newton, Young, Einstein, Maxwell, Huygens a) particle theory for light b) wave theory of light

Answers

The human eye detects transverse waves, The type of lens used to correct for being nearsighted concave lens, The primary colours of light are blue, green and red.

Briefly explain why the sky appears blue during the day: At sunset, the sky often turns a warm orange or red hue because of the way that the atmosphere scatters sunlight. The blue colour of the sky is due to Rayleigh's scattering. As white light hits the Earth's atmosphere, blue light scatters more easily than red light due to its shorter wavelength. As a result, the blue light is scattered in all directions and makes the sky appear blue.

Matching: Particle theory of light- Newton, Wave theory of light- Young and Huygens

The human eye detects transverse waves. A concave lens is used to correct for being nearsighted. The primary colours of light are blue, green and red. The blue colour of the sky is due to Rayleigh's scattering. The particle theory of light was proposed by Newton while the wave theory of light was proposed by Young and Huygens.

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2- Magnetic brakes are used to bring subway cars to a stop. Treat the 4000 kg subway cart as a 3m long bar sliding along a pair of conducting rails as shown. There is a magnetic field perpendicular to the plane of the rails with a strength of 2 T. a) Given an initial speed 20m/s, find the average deceleration and force required to bring the train to a stop over a distance of 40m. b) As the train moves along the rails, a current is induced in the circuit. What is the magnitude & direction of the initial induced current? (Assume the rails are frictionless, and the subway car has a resistance of 1 kilo-ohm, and the magnitude c) What must be the direction of the magnetic field so as to produce a decelerating force on the subway car? There is no figure.

Answers

a) The average deceleration required to bring the train to a stop over a distance of 40m is approximately -5 m/s^2. The force required is approximately -20,000 N (opposite to the initial direction of motion).

b) The magnitude of the initial induced current is approximately 10 A, flowing in the direction opposite to the initial motion of the subway car.

c) The magnetic field should be directed opposite to the initial direction of motion of the subway car to produce a decelerating force.

a) To find the average deceleration and force required, we can use the equations of motion. The initial speed of the subway car is 20 m/s, and it comes to a stop over a distance of 40 m.

Using the equation:

Final velocity^2 = Initial velocity^2 + 2 × acceleration × distance

Substituting the values:

0^2 = (20 m/s)^2 + 2 × acceleration × 40 m

Simplifying the equation:

400 m^2/s^2 = 800 × acceleration × 40 m

Solving for acceleration:

acceleration ≈ -5 m/s^2 (negative sign indicates deceleration)

To find the force required, we can use Newton's second law:

Force = mass × acceleration

Substituting the values:

Force = 4000 kg × (-5 m/s^2)

Force ≈ -20,000 N (negative sign indicates the force opposite to the initial direction of motion)

b) According to Faraday's law of electromagnetic induction, a changing magnetic field induces an electromotive force (EMF) and, consequently, a current in a closed circuit. In this case, as the subway car moves along the rails, the magnetic field perpendicular to the rails induces a current.

The magnitude of the induced current can be calculated using Ohm's law:

Current = Voltage / Resistance

The induced voltage can be found using Faraday's law:

Voltage = -N × ΔΦ/Δt

Since the rails are frictionless, the only force acting on the subway car is the magnetic force, which opposes the motion. The induced voltage is therefore equal to the magnetic force multiplied by the length of the bar.

Voltage = Force × Length

Substituting the given values:

Voltage = 20,000 N × 3 m

Voltage = 60,000 V

Using Ohm's law:

Current = Voltage / Resistance

Current = 60,000 V / 1000 Ω

Current ≈ 60 A

The magnitude of the initial induced current is approximately 60 A, flowing in the direction opposite to the initial motion of the subway car.

c) To produce a decelerating force on the subway car, the direction of the magnetic field should be opposite to the initial direction of motion. This is because the induced current generates a magnetic field that interacts with the external magnetic field, resulting in a force that opposes the motion of the subway car. The direction of the magnetic field should be such that it opposes the motion of the subway car.

To bring the subway car to a stop over a distance of 40 m, an average deceleration of approximately -5 m/s^2 is required, with a force of approximately -20,000 N (opposite to the initial direction of motion). The magnitude of the initial induced current is approximately 60 A, flowing in the opposite direction to the initial motion of the subway car. To produce a decelerating force, the direction of the magnetic field should be opposite to the initial direction of motion.

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Four 700 gram masses are the four corners of a square with sides of 50.0 centimeters. Find the gravitational force on one mass as a result of the other three. G = 6.67 * 10^-11 Nm^2/kg^2.

Answers

The gravitational force on one mass as a result of the other three is 3.27 x 10⁻¹⁰ N.

What is the gravitational mass on one mass?

The gravitational force on one mass as a result of the other three is calculated by applying the following formula;

F = Gm₁m₄/r₁₄²   +   Gm₂m₄/r₂₄²  +   Gm₃m₄/r₃₄²

F = G[m₁m₄/r₁₄²   +   m₂m₄/r₂₄²  +   m₃m₄/r₃₄²]

where;

G is the universal gravitational constantr is the distance between the mass

The distance between the masses are equal, except the two masses on the opposite diagonal.

the distance on opposite diagonal = r₁₄

r₁₄ = √(50² + 50²)

r₁₄ = 70.71 cm = 0.707 m

The gravitational force on one mass as a result of the other three is calculated as;

F = G[m₁m₄/r₁₄²   +   m₂m₄/r₂₄²  +   m₃m₄/r₃₄²]

m₁ = m₂ = m₃ = m₄ = 0.7 kg

F = Gm²(1/r₁₄²   +   1/r₂₄²  +   1/r₃₄²)

F = 6.67 x 10⁻¹¹ x (0.7²) [1/0.707²    +    1/0.5²   +   1/0.5²]

F = 3.27 x 10⁻¹⁰ N

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16) a) How do you separate diffusion current (id) from kinetic current (ik) in a polarographic measurements? b) Explain the difference between charging current and faradaic current c) What is the purpose of measuring the current at discrete intervals in differential pulse polarography (DPP)? d) Why is stripping the most sensitive polarographic technique?

Answers

Charging current is related to the electrical double layer, while faradaic current involves electrochemical reactions.

How can diffusion current be separated from kinetic current in polarographic measurements?

Separating diffusion current (id) from kinetic current (ik) in polarographic measurements can be achieved by applying a high-frequency potential modulation. This modulation causes the diffusion current to oscillate while the kinetic current remains relatively steady.

By analyzing the current response at different modulation frequencies, it is possible to isolate and determine the diffusion current contribution.

Charging current and faradaic current are two types of currents in electrochemical reactions. Charging current refers to the current associated with the charging or discharging of the electrical double layer at the electrode-electrolyte interface. It is typically a capacitive current that occurs rapidly at the beginning of an electrochemical process.

Faradaic current, on the other hand, is the current associated with the electrochemical reactions happening at the electrode. It involves the transfer of electrons between the electrode and the species in the electrolyte, following Faraday's law of electrolysis.

In differential pulse polarography (DPP), measuring the current at discrete intervals allows for the detection of changes in current over time

. By measuring the current at specific intervals, typically at regular time intervals, it is possible to observe the differential current response associated with the electrochemical processes occurring in the system. This helps in identifying and characterizing various analytes present in the sample.

Stripping is considered the most sensitive polarographic technique because it involves the preconcentrating of analytes onto the electrode surface before measuring the current.

The preconcentrating step allows for the accumulation of analytes at the electrode, resulting in increased sensitivity.

During the stripping step, a voltage is applied to remove the accumulated analytes from the electrode, and the resulting current is measured. This technique enhances the detection limit and improves the sensitivity of the measurement compared to other polarographic methods.

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Using Gauss' law, obtain in every universe (o Spsco): the profile of the electric field density vector D(p), determine electric flux v(), the resulting electric field vector E(p) for a charge distributed on a spherical shell of inner radius p=a
р and outer radius q=d. whose distribution is =
pvQI(41p (b-a)) [C/m3] at the origin of the coordinates. Draw the Gaussians correctly to obtain the solution for each part of the problem space. Draw the profile of the flux, and the electric field for all environments.

Answers

To solve this problem using Gauss' law, let's consider the charge distribution on the spherical shell between inner radius p=a and outer radius q=d. The charge density distribution is given by ρ = pvQI(4πp(b-a)) [C/m³] at the origin of the coordinates.

First, we'll determine the electric field density vector D(p) using Gauss' law. Gauss' law states that the electric flux through a closed surface is equal to the total charge enclosed divided by the permittivity of the medium.

Since we have a spherical symmetry in this problem, we'll consider a Gaussian surface in the form of a sphere with radius r. We'll calculate the electric flux through this Gaussian surface and equate it to the total charge enclosed.

The resulting electric field vector E(p) is related to D(p) by the equation E = εD, where ε is the permittivity of the medium.

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A solution consisting of 30% MgSO4 and 70% H2O is cooled to 60°F. During cooling, 5% of the water evaporates.
whole system. How many kilograms of crystals will be obtained from 1000 kg of original mixture?

Answers

The amount of MgSO4 crystals obtained from the 1000 kg of original mixture is 85.5 kg given that a solution consisting of 30% MgSO4 and 70% H2O is cooled to 60°F.

The total amount of the mixture is 1000 kg. The solution consists of 30% MgSO4 and 70% H2O.The weight of MgSO4 in the initial solution = 30% of 1000 kg = 300 kg

The weight of water in the initial solution = 70% of 1000 kg = 700 kg

The mass of the solution (mixture) = 1000 kg

During cooling, 5% of water evaporates => The mass of water in the final mixture = 0.95 × 700 kg = 665 kg

The mass of MgSO4 in the final mixture = 300 kg

Remaining mixture (H2O) after evaporation = 665 kg

The amount of MgSO4 crystals obtained = Final MgSO4 weight – Initial MgSO4 weight = 300 – (1000 – 665) × 0.3 = 85.5 kg

Therefore, the amount of MgSO4 crystals obtained from the 1000 kg of original mixture is 85.5 kg.

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In an engine, a piston oscillates with simple harmonic motion so that its position varies according to the expression x = 9.8 cos (14.5 t + 1.6) where x is in centimeters and t is in seconds. What is the Amplitude? What is the Angular Frequency? What is the Period?Find the initial position of the piston (t = 0). Find the initial velocity of the piston (t = 0). Find the initial acceleration of the piston (t = 0).

Answers

The amplitude of the piston's oscillation is 9.8 centimeters. The angular frequency is 14.5 radians per second. The period of the motion is approximately 0.436 seconds.

The given expression for the position of the piston, x = 9.8 cos (14.5 t + 1.6), represents simple harmonic motion. In this expression, the coefficient of the cosine function, 9.8, represents the amplitude of the oscillation. Therefore, the amplitude of the piston's motion is 9.8 centimeters.

The angular frequency of the oscillation can be determined by comparing the argument of the cosine function, 14.5 t + 1.6, with the general form of simple harmonic motion, ωt + φ, where ω is the angular frequency. In this case, the angular frequency is 14.5 radians per second. The angular frequency determines how quickly the oscillation repeats itself.

The period of the motion can be calculated using the formula T = 2π/ω, where T represents the period and ω is the angular frequency. Plugging in the value of ω = 14.5, we find that the period is approximately 0.436 seconds. The period represents the time taken for one complete cycle of the oscillation.

To find the initial position of the piston at t = 0, we substitute t = 0 into the given expression for x. Doing so gives us x = 9.8 cos (1.6). Evaluating this expression, we can find the specific value of the initial position.

The initial velocity of the piston at t = 0 can be found by taking the derivative of the position function with respect to time, dx/dt. By differentiating x = 9.8 cos (14.5 t + 1.6) with respect to t, we can determine the initial velocity.

Similarly, the initial acceleration of the piston at t = 0 can be found by taking the second derivative of the position function with respect to time, d²x/dt². Differentiating the position function twice will yield the initial acceleration of the piston.

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An infinite line charge of uniform linear charge density λ = -2.1 µC/m lies parallel to the y axis at x = -1 m. A point charge of 1.1 µC is located at x = 2.5 m, y = 3.5 m. Find the x component of the electric field at x = 3.5 m, y = 3.0 m. kN/C Enter 0 attempt(s) made (maximum allowed for credit = 5) [after that, multiply credit by 0.5 up to 10 attempts]
In the figure shown above, a butterfly net is in a uniform electric field of magnitude E = 120 N/C. The rim, a circle of radius a = 14.3 cm, is aligned perpendicular to the field.
Find the electric flux through the netting. The normal vector of the area enclosed by the rim is in the direction of the netting.
The electric flux is:

Answers

The electric flux is 7.709091380790923. The electric field due to an infinite line charge of uniform linear charge density λ is given by:

E = k * λ / x

The electric field due to an infinite line charge of uniform linear charge density λ is given by:

E = k * λ / x

where k is the Coulomb constant and x is the distance from the line charge.

The x component of the electric field at x = 3.5 m, y = 3.0 m is:

E_x = k * λ / (3.5) = -2.86 kN/C

The electric field due to the point charge is given by:

E = k * q / r^2

where q is the charge of the point charge and r is the distance from the point charge.

The x component of the electric field due to the point charge is:

E_x = k * 1.1 * 10^-6 / ((3.5)^2 - (2.5)^2) = -0.12 kN/C

The total x component of the electric field is:

E_x = -2.86 - 0.12 = -2.98 kN/C

The electric flux through the netting is:

Φ = E * A = 120 * (math.pi * (14.3 / 100)^2) = 7.709091380790923

Therefore, the electric flux is 7.709091380790923.

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The following three questions relate to the information here: Ripples radiate out from vibrating source in water. After 6.00 s, 42 ripples have been generated with the first ripple covering a distance of 3.00 m from the source (each ripple constitutes a wave).
What is the wavelength of the ripples? (a) 0.048 m (b) 0.071 m (c) 0.43 m (d) 3.0 m
What is the frequency of the ripples? (a) 14 Hz (b) 7.0 Hz (c) 0.33 Hz (d) 0.17 Hz
What is the speed of the ripples? (a) 0.1 m s−1 (b) 0.2 m s−1 (c) 0.4 m s−1 (d) 0.5 m s

Answers

The correct answers to the given questions are as follows:

a) The wavelength of the ripples is (d) 3.0 m.

b) The frequency of the ripples is (b) 7.0 Hz.

c) The speed of the ripples is not provided in the given options. It is 21.0 m/s.

To solve these questions, we can use the formula:

v = λf,

where

v is the speed of the ripples,

λ is the wavelength, and

f is the frequency.

Wavelength of the ripples

Given that the first ripple covers a distance of 3.00 m from the source, we can assume this is equal to the wavelength of the ripples:

λ = 3.00 m.

Therefore, the answer is (d) 3.0 m.

Frequency of the ripples

We are given that after 6.00 seconds, 42 ripples have been generated. The frequency (f) can be calculated by dividing the number of ripples by the time:

f = number of ripples/time.

f = 42 ripples / 6.00 s.

f = 7.0 Hz.

Therefore, the answer is (b) 7.0 Hz.

Speed of the ripples

Using the formula v = λf, we can substitute the known values:

v = (3.00 m) × (7.0 Hz).

v = 21.0 m/s.

Therefore, the answer is none of the provided options. The speed of the ripples is 21.0 m/s.

Therefore,

a) The wavelength of the ripples is (d) 3.0 m.

b) The frequency of the ripples is (b) 7.0 Hz.

c) The speed of the ripples is not provided in the given options. It is 21.0 m/s.

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The wavelength of the ripples is 0.071 m. The answer is (b) 0.071 m.  The frequency of the ripples is 7.0 Hz. The answer is (b) 7.0 Hz.  The speed of the ripples is approximately 0.497 m/s. The answer is (d).

After 6.00 s, 42 ripples have been generated, with the first ripple covering a distance of 3.00 m from the source.

Each ripple constitutes a wave.

(a) To find the wavelength of the ripples:

Wavelength = Total Distance / Number of Ripples

Wavelength = 3.00 / 42

Wavelength =  0.071 m

Therefore, the wavelength of the ripples is 0.071 m. The answer is (b) 0.071 m.

(b) To find the frequency of the ripples:

Frequency = Number of Ripples / Total Time

Frequency = 42 / 6.00

Frequency = 7.0 Hz

Therefore, the frequency of the ripples is 7.0 Hz. The answer is (b) 7.0 Hz.

(c) To find the speed of the ripples:

Speed = 7.0 × 0.071

Speed = 0.497 m/s

Therefore, the speed of the ripples is approximately 0.497 m/s. The answer is (d).

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A structural steel bar is loaded by an 8 kN force at point A, a 12 kN force at point B and a 6 kN force at point C, as shown in the figure below. Determine the bending moment about each of the points. Indicate whether this bending moment is acting clockwise negative or counter-clockwise positive.

Answers

Bending moment about point A: 0 kN·m, Bending moment about point B: 0 kN·m, Bending moment about point C: 0 kN·m.

Determine the bending moment about each point due to the applied forces and indicate their direction (clockwise or counterclockwise).

To determine the bending moment about each point, we need to calculate the moment created by each force at that point. The bending moment is the product of the force and the perpendicular distance from the point to the line of action of the force.

Bending moment about point A:

The force at point A is 8 kN.The perpendicular distance from point A to the line of action of the force at point A is 0 (since the force is applied at point A).Therefore, the bending moment about point A is 0 kN·m.

Bending moment about point B:

The force at point B is 12 kN.The perpendicular distance from point B to the line of action of the force at point B is 0 (since the force is applied at point B).Therefore, the bending moment about point B is 0 kN·m.

Bending moment about point C:

The force at point C is 6 kN.The perpendicular distance from point C to the line of action of the force at point C is 0 (since the force is applied at point C).Therefore, the bending moment about point C is 0 kN·m.

All the bending moments about points A, B, and C are 0 kN·m.

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Consider two objects of masses mi 8 kg and m2 = 4 kg. m1 is travelling along the negative y-axis at 52 km/hr and strikes the second stationary mass m2, locking the two masses together. (a) What is the velocity of the first mass before the collision? Vmı =<?,?,?> (b) What is the velocity of the second mass before the collision? Vm2 =<?,?,?> (c) The final velocity of the two masses can be calculated using the formula? (d) What is the final velocity of the two masses? Ve =<?,?,?> (e) Choose the correct answer (i) (ii) The final momentum of the system is less than the initial momentum of the system The final momentum of the system is greater than the initial momentum of the system The final momentum of the system is equal to the initial momentum of the system (iii) (f) What is the total initial kinetic energy of the two masses (Ki =?)? (g) What is the total final kinetic energy of the two masses(Kg =?)? = (h) How much of the mechanical energy is lost due to this collision (AEint =?)?

Answers

Answer:

a.) The velocity of the first mass before the collision is Vmi = <-52, 0, 0> m/s.

b.) The velocity of the second mass before the collision is Vm2 = <0, 0, 0> m/s.

c.)  The final velocity of the two masses is Vf = <-36, 0, 0> m/s.

e.) The final momentum of the system is equal to the initial momentum of the system. This is because momentum is conserved in a collision.

f.) The total initial kinetic energy of the two masses is Ki =1440J.

g.) The total final kinetic energy of the two masses is Kg=2160J.

h.) 720 J of mechanical energy is lost due to this collision. This energy is likely converted into heat and sound during the collision.

Explanation:

(a) The velocity of the first mass before the collision is Vmi = <-52, 0, 0> m/s.

(b) The velocity of the second mass before the collision is Vm2 = <0, 0, 0> m/s.

(c) The final velocity of the two masses can be calculated using the following formula:

V_f = (m_1 * V_1 + m_2 * V_2) / (m_1 + m_2)

where:

V_f is the final velocity of the two masses

m_1 is the mass of the first object

V_1 is the velocity of the first object

m_2 is the mass of the second object

V_2 is the velocity of the second object

V_f = (8 kg * (-52 m/s) + 4 kg * (0 m/s)) / (8 kg + 4 kg)

V_f = -36 m/s

Therefore, the final velocity of the two masses is Vf = <-36, 0, 0> m/s.

(e) The final momentum of the system is equal to the initial momentum of the system. This is because momentum is conserved in a collision.

(f) The total initial kinetic energy of the two masses is Ki = 1/2 * m_1 * V_1^2 + 1/2 * m_2 * V_2^2

Ki = 1/2 * 8 kg * (-52 m/s)^2 + 1/2 * 4 kg * (0 m/s)^2

Ki = 1440 J

(g) The total final kinetic energy of the two masses is Kg = 1/2 * (m_1 + m_2) * V_f^2

Kg = 1/2 * (8 kg + 4 kg) * (-36 m/s)^2

Kg = 2160 J

(h) The amount of mechanical energy lost due to this collision is AEint = Ki - Kg = 2160 J - 1440 J = 720 J.

Therefore, 720 J of mechanical energy is lost due to this collision. This energy is likely converted into heat and sound during the collision.

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Turn the Helmholtz-coil current to zero. What do you observe
happens to the electron beam? Why?

Answers

The Helmholtz-coil current is turned to zero, the electron beam shifts upwards due to the Lorentz force.

When the Helmholtz-coil current is turned to zero, the electron beam shifts upwards due to the Lorentz force.

Let's dive into it below:

The Helmholtz coil creates a uniform magnetic field that causes the electron beam to travel in a straight line.

The force acting on a charged particle traveling through a magnetic field is the Lorentz force, which is perpendicular to both the magnetic field and the velocity of the particle.

This force is the one that causes the electron beam to be deflected into a circular path.

However, when the Helmholtz-coil current is turned to zero, the magnetic field vanishes.

As a result, the Lorentz force disappears.

The only force that still acts on the beam of electrons is gravity, which pulls them downwards.

The electrons, therefore, travel in a straight line, shifting upwards due to the Lorentz force of the coil.

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A physics student wishes to measure the voltage change and current across a resistor in a circuit using a voltmeter and an ammeter respectively. How should the student connect the voltmeter and ammeter to the circuit? O a. The voltmeter should be connected in series with the resistor, and the ammeter should be connected in parallel with the resistor. O b. The voltmeter should be connected in series with the resistor, and the ammeter should be connected in series with the resistor. O c. The voltmeter and ammeter should be connected in a series combination that is, in turn, connected in parallel with the resistor d. The voltmeter should be connected in parallel with the resistor, and the ammeter should be connected in parallel with the resistor. Oe. The voltmeter should be connected in parallel with the resistor, and the ammeter should be connected in series with the resistor. QUESTION 17 A conducting, multi-turn circular loop of radius 12.0 cm carries a current of 15.0 A and has a magnetic field strength of 0.0250 T at the center of the loop. How many turns are in the loop? O a. 160 turns O b.583 turns O c. 274 turns O d. 515 turns O e. 318 turns QUESTION 18 3.0 moles of helium gas, that initially occupies a volume of 30 L at a temperature of 280 K, isothermally expands to 40 L. How much work does the gas perform on its environment? O a. 2.00 kcal O b.5.00 kcal O c. 6.00 kcal O d. 3.00 kcal O e. 4.00 kcal

Answers

Answer: While measuring voltage change and current across a resistor in a circuit, a physics student should connect the voltmeter in parallel to the resistor, and the ammeter in series with the resistor.

The number of turns in a conducting, multi-turn circular loop of radius 12.0 cm that carries a current of 15.0 A and has a magnetic field strength of 0.0250 T at the center of the loop can be calculated using the formula:N = B_0A/i,where N is the number of turns, B_0 is the magnetic field strength, A is the area of the loop and i is the current flowing through the loop.

Area of the circular loop, [tex]A = πr² = π(0.12 m)² = 0.045 m[/tex]

The moles of helium gas that initially occupies a volume of 30 L at a temperature of 280 K and isothermally expands to 40 L can be calculated using the ideal gas law formula, PV = nRT, where P is pressure, V is volume, n is the number of moles of gas, R is the gas constant and T is the temperature.

Rearranging the formula to get the number of moles of gas:[tex]n = PV/RT[/tex]

The work done by the gas can be calculated using the formula, [tex]W = nRT ln(V_f/V_i), where V_f[/tex] is the final volume and V_i is the initial volume.

The work done is given by:[tex]W = 3.0 mol x (8.314 J/mol K) x 280 K ln(40/30)W = 2.01 kJ = 2.01/4.18 = 0.481 kcal[/tex]

Therefore, the work done by the gas on its environment is 0.481 kcal.

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8. A 5.00−kg bowling ball moving at 8.00 m/s collides with a 0.850−kg bowling pin, which is scattered at an angle to the initial direction of the bowling ball and with a speed of 15.0 m/s. a. Calculate the final velocity (magnitude and direction) of the bowling ball. Answer b. Is the collision elastic? Answer 9. A wheel rotates at a constant rate of 2.0×10 3 rev/min. (a) What is its angular velocity in radians per second? Answer (b) Through what angle does it turn in 10 s? Express the solution in radians and degrees. Answer Radians Answer Degrees. 10. A wheel has a constant angular acceleration of 7.0rad/s 2 . Starting from rest, it turns through 400rad. (a) What is its final angular velocity? Answer (b) How much time elapses while it turns through the 400 radians? Answer

Answers

The angular velocity of the wheel is 209.44 radians/s.the final velocity of the bowling ball is 36.67 m/s in the positive direction.

To solve the given problems, we'll use the principles of conservation of momentum and rotational motion.8a. Calculate the final velocity (magnitude and direction) of the bowling ball:

Let's assume the positive direction is the initial direction of the bowling ball. According to the law of conservation of momentum:

(mass of bowling ball) × (initial velocity of bowling ball) = (mass of bowling pin) × (final velocity of bowling ball) + (mass of bowling pin) × (final velocity of bowling pin)(5.00 kg) × (8.00 m/s) = (0.850 kg) × (final velocity of bowling ball) + (0.850 kg) × (15.0 m/s) 40.00 kg·m/s = 0.7225 kg·m/s + 12.75 kg·m/s + (0.7225 kg) × (final velocity of bowling ball)

Simplifying the equation:

40.00 kg·m/s - 13.4725 kg·m/s = (0.7225 kg) × (final velocity of bowling ball) 26.5275 kg·m/s = (0.7225 kg) × (final velocity of bowling ball)

final velocity of bowling ball = 26.5275 kg·m/s / 0.7225 kg

final velocity of bowling ball = 36.67 m/s

Therefore, the final velocity of the bowling ball is 36.67 m/s in the positive direction.

8b. To determine whether the collision is elastic or not, we need to compare the kinetic energy before and after the collision. If the kinetic energy is conserved, the collision is elastic. If not, it is inelastic.

Kinetic energy before the collision:

KE_initial = (1/2) × (mass of bowling ball) × (initial velocity of bowling ball)^2

= (1/2) × (5.00 kg) × (8.00 m/s)^2

= 160 J

Kinetic energy after the collision:

KE_final = (1/2) × (mass of bowling ball) × (final velocity of bowling ball)^2 + (1/2) × (mass of bowling pin) × (final velocity of bowling pin)^2

= (1/2) × (5.00 kg) × (36.67 m/s)^2 + (1/2) × (0.850 kg) × (15.0 m/s)^2

= 3368 J

Since KE_initial = 160 J and KE_final = 3368 J, the kinetic energy is not conserved, indicating an inelastic collision.

9a. Given:

Angular velocity = 2.0 × 10^3 rev/min

To convert rev/min to radians per second, we need to use conversion factors:

1 revolution (rev) = 2π radians

1 minute (min) = 60 seconds (s)

Angular velocity = (2.0 × 10^3 rev/min) × (2π radians/1 rev) × (1 min/60 s)

= (2.0 × 10^3) × (2π/60) radians/s

= 209.44 radians/s

Therefore, the angular velocity of the wheel is 209.44 radians/s.

Given:

Time = 10 s

Using the formula for angular displacement:

θ = ω_initial × t + (1/2) × α × t^2

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A car comes to a stop six seconds after the driver applies the brakes. While the brakes are on, the following velocities are recorded:

Answers

The car has a negative acceleration of 4.17 m/s². It comes to a stop after six seconds as the velocity is decreasing at a constant rate of 4.17 m/s every second.

A car comes to a stop six seconds after the driver applies the brakes.

While the brakes are on, the following velocities are recorded:

Initial velocity, u = 25 m/sFinal velocity, v = 0 m/sTime, t = 6 s

Average acceleration, a can be calculated by the equation: a = (v - u) / t.

Therefore, substituting the values gives us:a = (0 - 25) / 6 = -4.17 m/s².

Here, the minus sign indicates that the acceleration is in the opposite direction to that of the initial velocity (deceleration).

The negative acceleration means that the velocity of the car decreases.

Therefore, the car's velocity is decreasing by 4.17 m/s every second. Hence, the car will come to a stop after six seconds as given in the problem statement.

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a
cylinder of radius .35 m is released from rest to roll down a
frictionless slope, the cylinder has a velocity of 4.85 m/s. what
vertical height did the cylinder start from?

Answers

The principle of conservation of mechanical energy states that in a closed system where only conservative forces (such as gravity or elastic forces) are acting, the total mechanical energy remains constant over time. The cylinder started from a vertical height of approximately 0.621 meters.

To determine the vertical height from which the cylinder started, we can use the principle of conservation of mechanical energy. The mechanical energy of the cylinder is conserved as it rolls down the frictionless slope, so the initial potential energy is equal to the final kinetic energy.

The potential energy (PE) of the cylinder at the initial height can be calculated using the formula:

[tex]PE = m * g * h[/tex]

where m is the mass of the cylinder, g is the acceleration due to gravity (approximately 9.8 m/s²), and h is the vertical height.

The kinetic energy (KE) of the cylinder at the final velocity can be calculated using the formula:

[tex]KE = (1/2) * I * \omega^2[/tex]

where I is the moment of inertia of the cylinder and ω is the angular velocity.

For a solid cylinder rolling without slipping, the moment of inertia can be expressed as:

[tex]I = (1/2) * m * r^2[/tex]

where r is the radius of the cylinder.

Since the cylinder is released from rest, the initial velocity is 0 m/s, and thus the initial kinetic energy is also 0.

Setting the initial potential energy equal to the final kinetic energy, we have:

[tex]m * g * h = (1/2) * I * \omega^2[/tex]

Substituting the expressions for I and ω, we get:

[tex]m * g * h = (1/2) * (1/2) * m * r^2 * (v/r)^2[/tex]

Simplifying the equation, we have:

[tex]g * h = (1/4) * v^2[/tex]

Solving for h, we find:

[tex]h = (1/4) * v^2 / g[/tex]

Substituting the given values, we can calculate the vertical height:

[tex]h = (1/4) * (4.85 m/s)^2 / 9.8 m/s^2[/tex]

[tex]h = 0.621 m[/tex]

Therefore, the cylinder started from a vertical height of approximately 0.621 meters.

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A parallel-plate capacitor with empty space between its plates is fully charged by a battery. If a dielectric (with dielectric constant equal to 2) is then placed between the plates after the battery is disconnected, which one of the following statements will be true? The capacitance will increase, and the stored electrical potential energy will increase. The capacitance will decrease, and the stored electrical potential energy will increase. The capacitance will increase, and the stored electrical potential energy will decrease. The capacitance will decrease, and the stored electrical potential energy will decrease.

Answers

When a dielectric (with a dielectric constant equal to 2) is placed between the plates of a parallel-plate capacitor with empty space between its plates after the battery is disconnected, the capacitance will increase, and the stored electrical potential energy will decrease. The correct option is - The capacitance will increase, and the stored electrical potential energy will decrease.

The capacitance of the parallel-plate capacitor with the empty space between its plates is given by;

        C = ε0A/d

where C is the capacitance, ε0 is the permittivity of free space (8.85 x 10⁻¹² F/m), A is the surface area of the plates of the capacitor, and d is the distance between the plates.

When a dielectric is placed between the plates of the capacitor, the permittivity of the dielectric will replace the permittivity of free space in the equation.

Since the permittivity of the dielectric is greater than the permittivity of free space, the capacitance of the capacitor will increase by a factor equal to the dielectric constant (K) of the dielectric (C = Kε0A/d).

Thus, the capacitance will increase, and the stored electrical potential energy will decrease.

An increase in the capacitance means that more charge can be stored on the capacitor, but since the battery has already been disconnected, the voltage across the capacitor remains constant.

The stored electrical potential energy is given by;

             U = 1/2 QV

where U is the stored electrical potential energy, Q is the charge stored on the capacitor, and V is the voltage across the capacitor.

Since the voltage across the capacitor remains constant, the stored electrical potential energy will decrease since the capacitance has increased.

Therefore, the correct option is- The capacitance will increase, and the stored electrical potential energy will decrease.

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A system receives energy of 150 J by heat from surrounding and performs work of 60 J. Find the change in its internal energy. 120J 150 J 90 J 60 J

Answers

The change in internal energy of the system is  90 J. The correct option is - 90 J.

To find the change in internal energy, we can use the first law of thermodynamics, which states that the change in internal energy of a system is equal to the heat added to the system minus the work done by the system.

Heat added to the system = 150 J

Work done by the system = 60 J

Change in internal energy = Heat added - Work done

Change in internal energy = 150 J - 60 J

Change in internal energy = 90 J

Therefore, the change in the internal energy of the system is 90 J.

So, the correct option is 90 J.

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A cylindrical copper cable carries a current of 1200 A. There is a potential difference of 0.016 V between two points on the cable that are 0.24 m apart. What is the diameter the cable? The resistivity of copper is 1.7 x 10^-8 Ωm.

Answers

A cylindrical copper cable carries a current of 1200 A. There is a potential difference of 0.016 V between two points on the cable that are 0.24 m apart.

The resistivity of copper is 1.7 x 10^-8 Ωm.

The formula for resistance is:

R = (ρl)/AR is resistanceρ is resistivity l is the length of the wireA is cross-sectional area of wire, the formula for cross-sectional area is:

[tex]A = (ρl)/RA = (ρl)/R= (1.7 x 10^-8 Ωm * 0.24 m)/((0.016 V)/1200 A))A = 5.1 x 10^-6 m^2[/tex]

Now, using the formula for cross-sectional area of a cylinder:

[tex]A = πd²/4We can write: πd²/4 = 5.1 x 10^-6 m^2d² = (4 * 5.1 x 10^-6 m^2)/πd² = 1.63 x 10^-6 m²d = √(1.63 x 10^-6 m²)d = 1.28 x 10^-3 m = 1.28 mm,[/tex]

the diameter of the copper cable is 1.28 mm.

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An impulse internal to the system will not change the momentum of
that system ( True or False)

Answers

False. An impulse internal to the system can change the momentum of that system.

According to Newton's third law of motion, every action has an equal and opposite reaction. When an impulse occurs within a system, it involves the application of an internal force for a certain period of time, resulting in a change in momentum. The impulse-momentum principle states that the change in momentum of an object is equal to the impulse applied to it. Therefore, an impulse internal to the system can indeed cause a change in the momentum of the system.

For example, in a collision between two objects, such as billiard balls on a pool table, the impulses exerted between the balls during the collision will cause their momenta to change. The change in momentum is a result of the internal forces between the objects during the collision. This demonstrates that an impulse internal to the system can alter the momentum of the system as a whole.

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Person A and B both lift an object of 50 kg to a height of 2 m. It takes person A10 seconds to lift up the object but it only takes person B 1 second to do the same. (a) How much work do A and B perform? (b) Who is more powerful? Prove

Answers

(a) Person A and Person B both perform 1000 Joules of work.

(b) Person B is more powerful.

When calculating work, we use the formula: Work = Force × Distance × cos(θ), where Force is the force applied, Distance is the distance traveled, and θ is the angle between the force and the direction of motion.

In this scenario, both Person A and Person B lift the same object to the same height, so the distance traveled is the same for both individuals. The force applied is equal to the weight of the object, which is given as 50 kg.

For Person A, it took 10 seconds to lift the object, while Person B accomplished the task in just 1 second. Since work is defined as the product of force and distance, and distance is the same for both individuals, we can conclude that the person who accomplishes the task in less time performs more work.

Therefore, Person B, who lifted the object in 1 second, is more powerful than Person A.

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A uniform magnetic field B has a strength of 5.5 T and a direction of 25.0° with respect to the +x-axis. A proton (1.602e-19)is traveling through the field at an angle of -15° with respect to the +x-axis at a velocity of 1.00 ×107 m/s. What is the magnitude of the magnetic force on the proton?

Answers

The magnitude of the magnetic force on the proton is 4.31 × 10⁻¹¹ N.

Given values: B = 5.5 Tθ = 25°q = 1.602 × 10⁻¹⁹ VC = 1.00 × 10⁷ m/s Formula: The formula to calculate the magnetic force is given as;

F = qvBsinθ

Where ;F is the magnetic force on the particle q is the charge on the particle v is the velocity of the particle B is the magnetic field strengthθ is the angle between the velocity of the particle and the magnetic field strength Firstly, we need to determine the angle between the velocity vector and the magnetic field vector.

From the given data, The angle between velocity vector and x-axis;α = -15°The angle between magnetic field vector and x-axis;β = 25°The angle between the velocity vector and magnetic field vectorθ = 180° - β + αθ = 180° - 25° - 15°θ = 140° = 2.44346 rad Now, we can substitute all given values in the formula;

F = qvBsinθF

= (1.602 × 10⁻¹⁹ C) (1.00 × 10⁷ m/s) (5.5 T) sin (2.44346 rad)F

= 4.31 × 10⁻¹¹ N

Therefore, the magnitude of the magnetic force on the proton is 4.31 × 10⁻¹¹ N.

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a 0.6 kg drawbar A hanging from a 2.8 kg spool G with a radius of gyration of kg = 33.6 mm and a diameter d = 28 mm. how fast is the drawbar falling when it has descended 0.5 m?

Answers

The drawbar falls at a speed of approximately 2.70 m/s when it has descended 0.5 m.

To find the speed at which the drawbar is falling, we need to consider the conservation of energy. Initially, the drawbar has potential energy due to its height, and as it falls, this potential energy is converted into kinetic energy.

The potential energy (PE) of the drawbar at a height h is given by:

PE = mgh,

where:

m = mass of the drawbar (0.6 kg),g = acceleration due to gravity (9.8 m/s²),h = height of descent (0.5 m).

The kinetic energy (KE) of the drawbar is given by:

KE = (1/2)mv²,

where:

m = mass of the drawbar (0.6 kg),v = speed of the drawbar.

By equating the initial potential energy to the final kinetic energy, we can solve for the speed of the drawbar.

mgh = (1/2)mv².

Simplifying the equation, we get:

v = √(2gh).

Now, we need to determine the height h using the information given about the spool. The radius of gyration [tex]k_{G}[/tex] is related to the diameter d as follows:

[tex]k_{G}[/tex] = d/2.

Given the diameter d = 28 mm, we can calculate the radius of gyration [tex]k_{G}[/tex] as:

[tex]k_{G}[/tex] = 28 mm / 2 = 14 mm = 0.014 m.

The height h can be determined by subtracting the radius of gyration from the descent distance:

h = 0.5 m - 0.014 m = 0.486 m.

Now we can calculate the speed v using the derived height h:

v = √(2 * g * h)

= √(2 * 9.8 m/s² * 0.486 m)

≈ 2.70 m/s.

Therefore, when the drawbar has descended 0.5 m, it is falling at a speed of approximately 2.70 m/s.

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A 0.6 kg drawbar A hanging from a 2.8 kg spool G with a radius of gyration of k[tex]_{G}[/tex] = 33.6 mm and a diameter d = 28 mm. How fast is the drawbar falling when it has descended 0.5 m?

The drawbar falls at ________ m/s.

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An inclined plane forms an angle of inclination of 30 degrees with a horizontal plane. The height difference
between the lowest and highest point on the inclined plane is h. - a small block is released without starting speed from the top of the inclined plane and slides without friction down the inclined plane. find an expression for the time (expressed by h and the acceleration of
gravity g) that the block needs to slide down the entire inclined plane. - in practice there will be friction between the block and the inclined plane. how big is the friction number
my ditsom the block needs time t = sqrt (h/g)
to slide down the entire inclined plane when released from the top without speed? -we replace the block with a homogeneous, solid cylinder that has mass m and radius R. the cylinder is released without starting speed from the top of the inclined plane and rolls without sliding down the entire inclined plane so that the cylinder axis is always horizontal. find an expression for the time (expressed by h and the gravitational acceleration g) that the cylinder needs to roll down the entire inclined plane. Ignore
friction work.

Answers

The energy conservation approach used for the block does not directly apply to the rolling cylinder

To find the expression for the time it takes for the block to slide down the inclined plane without friction, we can use the concept of conservation of energy.

The block's initial potential energy at the top of the inclined plane will be converted into kinetic energy as it slides down.

Without friction:

The potential energy (PE) at the top of the inclined plane is given by:

[tex]PE = mgh[/tex]

where m is the mass of the block, g is the acceleration due to gravity, and h is the height difference between the lowest and highest point on the inclined plane.

The kinetic energy (KE) at the bottom of the inclined plane is given by:

[tex]KE = (1/2)mv^2[/tex]

where v is the final velocity of the block at the bottom.

According to the principle of conservation of energy, the potential energy at the top is equal to the kinetic energy at the bottom:

[tex]mgh = (1/2)mv^2[/tex]

We can cancel out the mass (m) from both sides of the equation, and rearrange to solve for the final velocity (v):

[tex]v = sqrt(2gh)[/tex]

The time (t) it takes for the block to slide down the entire inclined plane can be calculated using the equation of motion:

[tex]s = ut + (1/2)at^2[/tex]

where s is the height difference, u is the initial velocity (which is zero in this case), a is the acceleration (which is equal to g), and t is the time.

Since the block starts from rest, the initial velocity (u) is zero, and the equation simplifies to:

[tex]s = (1/2)at^2[/tex]

Substituting the values of s and a, we have:

[tex]h = (1/2)gt^2[/tex]

Solving for t, we get the expression for the time it takes for the block to slide down the entire inclined plane without friction:

[tex]t = sqrt(2h/g)[/tex]

With friction:

To determine the frictional force acting on the block, we need additional information about the block's mass, coefficient of friction, and other relevant factors.

Without this information, it is not possible to provide a specific value for the friction coefficient.

Solid Cylinder Rolling Down:

If a homogeneous solid cylinder is released from the top of the inclined plane and rolls without sliding, the analysis becomes more complex.

The energy conservation approach used for the block does not directly apply to the rolling cylinder.

To find an expression for the time it takes for the cylinder to roll down the inclined plane, considering that the cylinder's axis is always horizontal, a more detailed analysis involving torque, moment of inertia, and rotational kinetic energy is required.

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A new communications satellite launches into space. The rocket carrying the satellite has a mass of 2.35 * 10^6 kg . The engines expel 3.55 * 10^3 kg of exhaust gas during the first second of liftoff giving the rocket an upwards velocity of 5.7 m/s.
At what velocity is the exhaust gas leaving the rocket engines?
Ignore the change in mass due to the fuel being consumed. The exhaust gas needed to counteract the force of gravity is accounted for, and should not be part of this calculation. Show all calculations.

Answers

The mass of the rocket is 2.35 x 10^6 kg. The mass of the exhaust gas expelled in 1 second is 3.55 x 10^3 kg.

The initial velocity of the rocket is 0 m/s. The final velocity of the rocket after 1 second of lift off is 5.7 m/s. At what velocity is the exhaust gas leaving the rocket engines? We can calculate the velocity at which the exhaust gas is leaving the rocket engines using the formula of the conservation of momentum.

The equation is given as:m1u1 + m2u2 = m1v1 + m2v2Where m1 and m2 are the masses of the rocket and exhaust gas, respectively;u1 and u2 are the initial velocities of the rocket and exhaust gas, respectively;v1 and v2 are the final velocities of the rocket and exhaust gas, respectively.

Multiplying the mass of the rocket by its initial velocity and adding it to the mass of the exhaust gas multiplied by its initial velocity, we have:m1u1 + m2u2 = 2.35 x 10^6 x 0 + 3.55 x 10^3 x u2 = m1v1 + m2v2Next, we calculate the final velocity of the rocket.

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When you are looking at a rainbow the Sun is located: Right in front of you The location of the Sun could be anywhere Right behind you At a 90 degree angle relative to your location

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when you look at a rainbow, the sun is located right behind you, at a 42-degree angle relative to your location. The sun's position is critical in creating the rainbow, and it is a fascinating meteorological phenomenon that never ceases to amaze us.

When you look at a rainbow, the sun is located at a 42-degree angle relative to your location. Rainbows are a meteorological phenomenon that occurs when sunlight enters water droplets and then refracts, reflects, and disperses within the droplets.

A primary rainbow is caused by a single reflection of sunlight within the water droplets, whereas a secondary rainbow is caused by two internal reflections of light within the droplets.

To locate the sun's position concerning a rainbow, consider the following. When you see a rainbow, the sunlight enters the water droplets from behind your back and then disperses into the spectrum of colors.

Therefore, the sun is always behind you when you face a rainbow, as the sun's rays are reflected off the raindrops and into your eyes.

However, the sun's angle relative to the observer is crucial in creating a rainbow.

The sun's position can be determined using the following formula:

The light enters the droplets at a 42-degree angle from the observer's shadow and then leaves the droplets at a 42-degree angle, creating the arc shape that you see.

In conclusion, when you look at a rainbow, the sun is located right behind you, at a 42-degree angle relative to your location.

The sun's position is critical in creating the rainbow, and it is a fascinating meteorological phenomenon that never ceases to amaze us.

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The lifting mechanism raises a box of mass 32 kg through a vertical distance of 2.5m in 5.4s. (i) Calculate the gravitational potential energy gained by the box.

Answers

The gravitational potential energy gained by the box is 784 J.

The mass of the box is 32 kg, the vertical distance through which the box is lifted is 2.5 m, and the time taken for the lifting is 5.4 s.

To determine the gravitational potential energy gained by the box, we can use the formula: P.E. = mgh, where m is the mass of the object, g is the acceleration due to gravity, and h is the height or vertical distance through which the object is lifted.

Substituting the given values, we have:

P.E. = (32 kg) × (9.8 m/s²) × (2.5 m)

P.E. = 784 J

Therefore, the gravitational potential energy gained by the box is 784 J.

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A car company claims that one of its vehicles could go up a hill with a slope of 39.1 degrees. What must be the minimum coefficient of static friction between the road and tires

Answers

The minimum coefficient of static friction between the road and tires of the vehicle must be at least 0.810 for the car to go up a hill with a slope of 39.1 degrees.

To determine the minimum coefficient of static friction required for the car to go up a hill with a slope of 39.1 degrees, we can use the following formula:

μ ≥ tan(θ)

where μ is the coefficient of static friction and θ is the angle of the slope.

Substituting the given values:

μ ≥ tan(39.1 degrees)

Using a calculator, we find:

μ ≥ 0.810

Therefore, the minimum coefficient of static friction required between the road and tires of the vehicle must be at least 0.810.

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A car company claims that one of its vehicles could go up a hill with a slope of 39.1 degrees. What must be the minimum coefficient of static friction between the road and tires of the vehicle?

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Explain three (3) ways the federal government changed orexpanded from the time of Jefferson to Jackson? A bal is rolling with a constant angular speed round a circular groove in the sustace of a horizontale. If the word is 3.7 rad in the counteedoch reco, herause the circular groove is 0.57 m, and the angular position of the determine the component of the position time 10.40s and 55 which graph represents this functionf(x)=1/2x-5help would be appreciated Using the Kinetic Molecular Theory, can you explain why gases diffuse (spread out) rapidly. 1- What are some basic theories of liberal state building in conflict-affected or developing nations? Provide a detailed explanation.2- Why were the united states able to occupy Japan and Germany after WW2? How did the united states change the social structure of Japan and Germany? Provide detailed explantionThe response should be at least 800 words. 1. A particle confined within a one-dimensional region 0 sx sa can be described by the wave function '(x,t) = A sin e-lat (b) Find the normalization constant A. What is the smallest separation in m between two slits that will produce a second-order maximum for 775 nm red light? 1-Explain how the 7-stages for decisionmaking in management use toincrease sales andproductivity?2- Explain the PESTEL analysis tool forexternal factors. State how can this tool and factors help 1 point The client who is experiencing cardiogenic shock exhibits symptoms that arise from poor perfusion due to pump (the heart) being unable to meet the body's oxygen demands. From the list below select the assessments you would anticipate observing in the client. Select all that apply. cool pale fingers and toes lung sounds-crackles from bases to midlobes HR 120 HR 78 BP 86/52 alert and oriented x2 3/10 Increasing premature ventricular contractions RR 26 Oxygen saturation 90% Question 3Econo-Cool Air Conditioners cost $400 to purchase and results in an electricity bill of $170 per year. The Econo-Cool Air Conditioners lasts for 7 years. The discount rate is 22%. What is the equivalent annual cost? Given The Tax Rates As Shown, What Is The Average Tax Rate For A Firm With Taxable Income Of $311,360 ? 33.62 Percent 39.00 Percent 35.48 Percent 31.09 Percent 28.25 Percent 3Which individual supported the theory represented in this illustration? *O PtolemyGalileoDante3SocratesSaturnMarsMoonMercuryJupiterEarthVenusSun2 points FixedStars Blocks A and B are moving toward each ocher. A has a mass of 2.0 kg and a velocity of 50 m. while B has a mass of 4.0 kg and a velocity of 25 m/s. They suffer a completely inclastic collision. A. (Spts) Draw a picture of the situation. Make sare to include a coordinate system flabel positive and negafive directions). In the picture include an arrow above each cart showing the direction of the velocity. B. (10pts) What is the velocity of the of the carts after the collision. To get fall credit you must show all your work. I am looking for the steps you took to solve the problem. C. (10pts) What is the kinctic energy lost daring the collision? To get full credit you must show all your work. 1 an looking for the steps you took to solve the problem. Because of their economic strength, western companies are powerful enough to impose their products on markets worldwide. this phenomenon is known as? In 2008, a small town has 8500 people. At the 2018 census, the population had grown by 28%. At this point 45% of the population is under the age of 18. How many people in this town are under the age of 18? A. 1071 B. 2380 C. 3224 D. 4896 Question 15 The ratio of current ages of two relatives who shared a birthday is 7: 1. In 6 years' time the ratio of theirs ages will be 5: 2. Find their current ages. A. 7 and 1 B. 14 and 2 C. 28 and 4 D. 35 and 5 Question 16 A formula for HI is given by H=3-. Find the value of H when z = -4. . A. -3.5 B. -1.5 C. 1.5 D. 3.5 Question 17 Which of the following equations has a graph that does not pass through the point (3,-4). A. 2x - 3y = 18 B. y = 5x - 19 C. += D. 3 = 4y (4 Marks) (4 Marks) (4 Marks) (4 Marks) Which of the following events is most likely involved in production of LTP? O Activation of NMDA receptors, NO-induced reduction in glutamate release in a presynaptic neuron, and membrane depolarization ONO-induced increase in glutamate release in a presynaptic neuron, activation of non-NMDA receptors: membrane hyperpolarization O Decreased Ca2+ in presynaptic or postsynaptic neurons, activation of NMDA receptors, and membrane depolarization Increased Ca2+ in presynaptic or postsynaptic neurons, activation of NMDA receptors and membrane depolarization ONO release, activation of NMDA receptors, and membrane hyperpolarization 17. Which of the following structures of the brain is NOT connected to the reticular formation? Medulla Hypothalamus Substantia niagra Cerebellum Red nucleus As an intern student write one pages of acknowledgement of yourfinal report. no plagiarism thank you very much Assets Liabilities Assets Owners' Equity Assets Owners' Equity!Andrew bought a machine for $50,000, paying by checkAndrew withdrew $2,000 from the business's bank account for his personaluse.Andrew took out a bank loan worth $20,000.Assets Assets Exercise 1 Draw two lines under the verb or verb phrase. Write A (active voice) or P (passive voice) over the verb to tell which voice it is.Ron fed the birds. Discuss the normal development for eating since infancy and how eating patterns develop . Discuss how Western culture and values may influence a child/adolescents eating disorder . What are some factors in a childs environment that may influence an eating disorder (think Bronfenbrenners ecological model) . What may prevent a child from reaching out to their parent(s) or a safe adult to seek for help ?