Find the total translational kinetic energy of
3 L of oxygen gas held at a temperature of
3◦C and a pressure of 2 atm.
Answer in units of J.

When the sum of external forces and sum of the external torques on a body are both zero, we conclude that the body is in state of static equilibrium.

When the sum of external forces and the sum of external torques on body are both zero, we can say that the body is in state of static equilibrium.

In this state, the body is not accelerating, and velocity and angular velocity are constant (or zero). The sum of external forces on the body is equal to zero, which means that net force acting on body is zero. Similarly, sum of external torques on body is also equal to zero, which means that the net torque acting on body is zero.

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The exact direction will depend on your location and the time of year, but in general, the stars appear to move approximately 15 degrees per hour

Assuming that you are in the Northern Hemisphere, Polaris (also known as the North Star) is located very close to the north celestial pole, which is the point in the sky around which the stars appear to rotate.

Therefore, fifteen minutes later, the Big Dipper will have moved to the west of its current position, which means that it will appear to have moved in the direction of the west.

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Only the resistor connected in series which is resistor A will have the least current passing through it.

In this problem, we have some resistors that are connected in series and some in parallel.

The formula of resistors connected in series is given as;

R(series = R1 + R2 + R3 + ....+ Rn

The formula for resistors connected in parallel are

R(parallel) = 1/ R1 + 1/R2 + 1 / R3 +...+ 1/Rn

In this case, we have to assume that the voltage passing through the circuit is uniform and let's assume is 2V

V = IR

I = V/R

From the equation above, we can see that only the series resistance will have a small current passing through it.

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In this activity, increasing the stimulus frequency had a direct impact on the force developed by the isolated whole skeletal muscle. As the frequency of the stimulus increased, the muscle experienced a higher rate of nerve impulses. This led to a greater number of muscle fibers being activated, resulting in an increased force of contraction.

At lower frequencies, the muscle had sufficient time to relax between stimuli, allowing for individual twitches to be distinguished. However, as the frequency increased, the time between stimuli decreased, and the muscle could not fully relax. This caused summation, where the force of the subsequent contractions added up, resulting in a stronger muscle contraction overall.

Eventually, the stimulus frequency reached a point where the muscle contractions fused together, leading to tetanus – a sustained, maximal force contraction. This is the point at which the muscle developed its greatest force in response to the increasing stimulus frequency.

The results from this activity may have aligned with your prediction if you understood the relationship between stimulus frequency and muscle force. As frequency increases, so does the force generated by the muscle, up to the point of tetanus. Overall, the experiment demonstrated the essential role of stimulus frequency in modulating the force developed by whole skeletal muscles.

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The electric force of the molecule on the proton is  N = kg m / [tex]s^2[/tex].

To calculate the electric force of a molecule on a proton, we need to know the charge of the molecule and the distance between the molecule and the proton.

If the molecule has a net charge of q, and the distance between the molecule and the proton is r, then the electric force between them is given by Coulomb's law:

F = kqq_proton / r^2

where k is the Coulomb constant (8.9875 x 10^9 N m^2/C^2), and q_proton is the charge of the proton (which is positive and has a magnitude of 1.6022 x 10^-19 C).

The units of the electric force depend on the units used for charge (C) and distance (m). If we express q in Coulombs, r in meters, and F in Newtons, then the units of the electric force can be written as:

N = ([tex]N m^2/C^2[/tex]) * C * C / [tex]m^2[/tex]

which simplifies to:

N = kg m / [tex]s^2[/tex]

Therefore, the units of the electric force are Newtons (N).

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The minimum angle from which a pendulum can be dropped so that it just makes it around the peg without the string going slack can be calculated using the conservation of energy principle.

Let's assume that the length of the pendulum is L and the radius of the peg is r.

The potential energy of the pendulum at its maximum height (when it is just about to be released) is equal to its kinetic energy at its lowest point (when it just makes it around the peg without the string going slack).

Therefore, we can equate these two energies as follows:

mgh = (1/2)mv²

where m is the mass of the pendulum, g is the acceleration due to gravity, h is the height from which the pendulum is dropped, and v is the velocity of the pendulum at its lowest point.

Since the velocity of the pendulum at its lowest point is zero, we can simplify the above equation to:

h = (1/2)(v²/g)

Now, we can use the conservation of energy principle to determine the velocity of the pendulum at its lowest point. The total energy of the pendulum is constant and is equal to the sum of its potential energy (mgh) and its kinetic energy

(1/2)mv².

Therefore, we can write:

mgh = (1/2)mv²

Simplifying this equation, we get:

v² = 2gh

Substituting this value of v² into the equation for h, we get:

h = (1/2)(2gh/g)

h = h

This means that the height from which the pendulum is dropped does not depend on its mass. Therefore, the minimum angle from which the pendulum can be dropped so that it just makes it around the peg without the string going slack is given by:

θ = sin⁻¹(r/L)

where θ is the minimum angle in radians, r is the radius of the peg, and L is the length of the pendulum. To convert the angle from radians to degrees, we can use the formula:

θ(degrees) = (θ(radians) / 180)/π

where π is the mathematical constant pi.

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The rated secondary load current of a transformer can be calculated using the formula:

I = VA/V

where I is the current, VA is the apparent power rating of the transformer, and V is the voltage of the secondary winding.

In this case, the transformer is a step-down transformer, which means the secondary voltage is lower than the primary voltage. The secondary voltage is rated at 120 VAC, so we can use this value for V.

The apparent power rating of the transformer is given as 600 VA, so we can use this value for VA.

Substituting the values into the formula, we get:

I = 600 VA / 120 V

I = 5 amperes

Therefore, the rated secondary load current of the transformer is 5 amperes, so the correct answer is option (C).

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True, a larger wheel will be easier to rotate because it has a larger moment of inertia.

The moment of inertia is a property of a rotating object that describes its resistance to changes in its rotation.
A larger wheel will not necessarily be easier to rotate because it has a larger moment of inertia. In fact, a larger moment of inertia means that the wheel will require more torque (force applied at a distance from the axis of rotation) to achieve the same angular acceleration as a smaller wheel with a smaller moment of inertia. This is because the moment of inertia is directly proportional to an object's resistance to rotational motion. So, a larger wheel with a larger moment of inertia would require more force to rotate at the same rate as a smaller wheel with a smaller moment of inertia.

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Yes, you can drive your car in such a way that the distance it covers is (a) greater than, (b) equal to, but not  (c) less than the magnitude of its displacement.

(a) The distance covered is greater than the magnitude of its displacement when you take a non-linear path or have multiple changes in direction. In this case, the displacement is the straight-line distance between the starting and ending points, while the distance covered accounts for the entire path traveled.
(b) The distance covered is equal to the magnitude of its displacement when you drive in a straight line without changing direction. In this scenario, both the distance traveled and the straight-line distance between the starting and ending points are the same.
(c) The distance covered cannot be less than the magnitude of its displacement, as displacement is the shortest distance between two points. The distance traveled will always be equal to or greater than the displacement.

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A hot low density gas such as any the colorful nebulae imaged by the hubble space telescope emits a spectrum known as emission lines.

Density is a physical property of matter that measures its mass per unit of volume. It is expressed in terms of kilograms per cubic meter (kg/m3) and is an important factor in determining an object's ability to float or sink in a liquid or a gas. Density is also used to calculate the specific gravity of a substance, which compares the densities of two different substances.

These lines are created when electrons in the gas are excited by photons and then transition to a lower energy state. The emission lines correspond to specific wavelengths of light and can be used to identify elements, as each element has a unique set of emission lines. This can be used to identify the elements present in the gas and gives an indication of its temperature and density.

The temperature of a hot low-density gas is usually lower than that of the surrounding environment. This is because the gas has fewer collisions with other particles and hence, the energy transfer from these collisions is lower. As the temperature of the gas decreases, its density also decreases. This is because the gas molecules have less kinetic energy, so they are less likely to collide with each other and form a denser structure.

The density of a hot low-density gas is usually lower than that of the surrounding environment. This is because the gas has fewer collisions with other particles and hence, the energy transfer from these collisions is lower. As the density of the gas decreases, its temperature also decreases. This is because the gas molecules have less kinetic energy, so they are less likely to collide with each other and form a denser structure.

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Multiple pulleys in combination can increase the mechanical advantage of the system.

False.

A pulley is a simple machine that changes the direction of the force applied to it. A single pulley can only change the direction of the force required to lift an object, and it does not increase the mechanical advantage of the system.

Mechanical advantage refers to the ratio of the output force to the input force in a system. It is a measure of the amount by which a machine can multiply the force applied to it. In a simple pulley system, the mechanical advantage is equal to 1 because the output force is the same as the input force.

However, the mechanical advantage can be increased by using multiple pulleys in combination, such as in a block and tackle system. In a block and tackle system, several pulleys are arranged in such a way that the rope or cable passes through them multiple times. This arrangement multiplies the mechanical advantage of the system, making it easier to lift heavy objects.

So, in summary, a single pulley does not increase the mechanical advantage when lifting a weight. It only changes the direction of the force applied to the system. Multiple pulleys in combination can increase the mechanical advantage of the system.

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The work done on the system during an adiabatic free expansion is equal to the change in internal energy of the system.

Due to the adiabatic nature of the process, the change in the system's internal energy is equal to the change in the system's total energy, which is equal to the opposite of the change in potential energy.

As a result, the work accomplished is equal to the system's potential energy at the final volume less its potential energy at the initial volume. Since the system is perfect, PV, where P is the pressure and V is the volume, gives the system's potential energy.

Since P1 and P2 are the pressures before and after the expansion, respectively, the work done on the system is equal to −(20L×P2 - 10L×P1).

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In the celestial sphere model, the Sun's position along the western horizon at sunset changes due to the Earth's rotation on its axis.

The celestial sphere is an imaginary sphere with the observer at its center. It is used to map the positions of celestial objects such as stars, planets, and the Sun.

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The force of friction acts in the direction opposite to the direction of motion, so it acts up the inclined plane in this case. We can use the following equations of motion to solve for the force of friction:

v^2 = u^2 + 2as

where v is the final velocity, u is the initial velocity (which is zero in this case), a is the acceleration, s is the distance traveled, and we can use the following equation to relate the force of friction to the normal force:

f_friction = μ_k N

where μ_k is the coefficient of kinetic friction and N is the normal force, which is the component of the weight of the block that is perpendicular to the inclined plane.

First, we need to find the distance traveled by the block down the incline. We can use trigonometry to determine the height of the incline:

h = sin(30°) x length of incline = 0.5 x length of incline

The length of the incline is not given in the problem, so we can leave it as a variable. The distance traveled down the incline is equal to the length of the incline multiplied by the sine of the angle of inclination:

s = length of incline x sin(30°) = 0.5 x length of incline

Now we can use the equation of motion to solve for the final velocity:

v^2 = u^2 + 2as

v^2 = 0 + 2 x 3.0 m/s^2 x 0.5 x length of incline

v^2 = 3.0 m^2/s^2 x length of incline

The final velocity is also given by:

v = √(2gh)

where g is the acceleration due to gravity and h is the height of the incline. Substituting the value of h we found earlier:

v = √(2gh) = √(2 x 9.8 m/s^2 x 0.5 x length of incline) = √(9.8 m^2/s^2 x length of incline)

Now we can equate the two expressions for v and solve for the length of the incline:

3.0 m^2/s^2 x length of incline = 9.8 m^2/s^2 x length of incline

length of incline = 3.27 m

Now we can use the length of the incline to find the normal force:

N = mg cos(30°) = 1.8 kg x 9.8 m/s^2 x cos(30°) = 15.26 N

Finally, we can use the coefficient of kinetic friction to find the force of friction:

f_friction = μ_k N = 0.23 x 15.26 N = 3.51 N

Therefore, the magnitude of the force of friction acting on the block is approximately 3.5 N, which is closest to option (3) 3.4 N.

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True . If you increase the time over which a force is applied, you can decrease the magnitude of the force and still achieve the same change in momentum.

This concept is related to the Impulse-Momentum Theorem, which states that the impulse (force multiplied by time) is equal to the change in momentum.

To break it down step-by-step:
1. Impulse (I) is calculated as Force (F) multiplied by Time (t): I = F * t
2. Change in momentum (Δp) is equal to the impulse: Δp = I
3. When you increase the time (t) while maintaining the same change in momentum (Δp), you can decrease the force (F) since their product remains constant.

So, by increasing the time over which a force is applied, you can decrease the magnitude of the force while still achieving the same change in momentum.

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The woman supplied an average power of 625 W while climbing the stairway.

To find the average power the woman supplied, we need to use the formula:

average power = work done / time

The work done is equal to the change in potential energy of the woman as she climbs the stairs. The change in potential energy is given by:

ΔPE = mgh

where m is the mass of the woman, g is the acceleration due to gravity, and h is the height of the stairway.

So, ΔPE = (62.0 kg) x (9.81 m/s^2) x (4.28 m) = 2627 J

The time taken by the woman is 4.20 s.

Therefore, the average power she supplied is:

average power = work done / time = 2627 J / 4.20 s ≈ 625 W

Therefore, the woman supplied an average power of 625 W while climbing the stairway.

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The correct option is (2) 0.81 kN (since 0.81 kN is the closest option to 0.35 kN).

To solve this problem, we can use Newton's second law of motion, which states that the net force acting on an object is equal to its mass times its acceleration: F_net = m*a.

In this case, the person has a weight of 0.70 kN, which means that the force of gravity acting on them is 0.70 kN. The elevator is accelerating upward with an acceleration of 1.5 m/s^2. Therefore, the net force acting on the person can be found as follows:

F_net = ma = (0.70 kN)(1.5 m/s^2) = 1.05 kN

The magnitude of the force of the elevator floor on the person is equal in magnitude but opposite in direction to the net force acting on the person, which is 1.05 kN. Therefore, the answer is:

Magnitude of force = 1.05 kN - 0.70 kN = 0.35 kN

Therefore, the correct option is (2) 0.81 kN (since 0.81 kN is the closest option to 0.35 kN).

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The length of a simple pendulum with a period on Earth of 6.0 seconds is nearly 8.95 meters.

A simple pendulum can be described as a device where its point mass is attached to a light inextensible string and suspended from a fixed support. The vertical line passing through the fixed support is the mean position of a simple pendulum.

To calculate the length, we can use the formula for the period of a simple pendulum:

T = 2π√(L/g), where T is the period, L is the length, and g is the acceleration due to gravity (approximately 9.81 m/s² on Earth).

First, we'll rearrange the formula to solve for L:
L = (T² * g) / (4π²)

Now, plug in the given period (T = 6.0 seconds) and the value of g (9.81 m/s²):
L = (6.0² * 9.81) / (4 * π²)

Calculate the result:
L ≈ 8.95 meters

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The reflection coefficient is approximately 0.025, which means that 2.5% of the incident wave intensity is reflected.

The amount of energy that is reflected depends on the difference in acoustic impedance between the two materials. Acoustic impedance is the product of the density and the speed of sound in the material.

[tex]R = [(Z2 - Z1)/(Z2 + Z1)]^2[/tex]

Substituting the values into the formula for the reflection coefficient, we get:

[tex]R = [(Z2 - Z1)/(Z2 + Z1)]^2[/tex]

[tex]R = [(1.1Z1 - Z1)/(1.1Z1 + Z1)]^2[/tex]

[tex]R = [(0.1Z1)/(2.1Z1)]^2[/tex]

[tex]R = 0.025[/tex]

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The elongation of the spring is approximately 0.126 meters.

To find the elongation of the spring when the elastic potential energy stored in the spring is 0.8 J and the spring constant is 100 N/m, we will use the formula for elastic potential energy:
E = (1/2) * k * x^2
where E is the elastic potential energy, k is the spring constant, and x is the elongation of the spring.

E = 0.8 J
k = 100 N/m

Rearrange the formula to solve for x:
x^2 = (2 * E) / k

Plug in the values:
x^2 = (2 * 0.8 J) / 100 N/m

Calculate the elongation (x):
x = √(1.6 / 100) = √0.016

x ≈ 0.126 meters

So, the elongation of the spring is approximately 0.126 meters.

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Large telescopes are usually reflecting rather than refracting for several reasons.

Firstly, a lens must have two precision surfaces, while a mirror needs only one, making mirrors easier and cheaper to manufacture for larger sizes. Secondly, lenses absorb light, while mirrors do not, leading to a loss of brightness and contrast in refracting telescopes. Additionally, lenses are subject to chromatic aberration, where different colors of light are focused at slightly different points, causing blurring and distortion. Finally, heavy lenses, which can only be supported at their edges, tend to deform under their own weight, whereas mirrors can be supported from behind, allowing for larger sizes and sharper images.

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The force exerted by the car on the truck is equal to 7500 N, and the force exerted by the truck on the car is equal to -7500 N.

According to Newton's third law of motion, for every action, there is an equal and opposite reaction. Therefore, during the collision between the car and the truck, the force exerted by the car on the truck is equal in magnitude but opposite in direction to the force exerted by the truck on the car.

To determine the force exerted by the car on the truck, we can use the formula for impulse, which is the change in momentum of an object over a given period of time:

Impulse = Force x Time = Δp

where Δp is the change in momentum of the object and t is the time interval during which the force is applied.

In this case, the bumpers of the car and truck lock together, which means that they move as a single unit after the collision. Therefore, we can apply the law of conservation of momentum, which states that the total momentum of an isolated system remains constant.

Initially, the car has a momentum of:

p_car_initial = m_car * v_car_initial = 1500 kg * 25.0 m/s = 37500 kg m/s

Since the truck is at rest initially, its momentum is zero:

p_truck_initial = 0

After the collision, the two vehicles move together as a single unit with a common final velocity. Let the final velocity of the car-truck system be v_final.

Using conservation of momentum:

p_car_initial + p_truck_initial = (m_car + m_truck) * v_final

37500 kg m/s + 0 = (1500 kg + 4500 kg) * v_final

v_final = 5.0 m/s

Therefore, the momentum of the car-truck system after the collision is:

p_final = (1500 kg + 4500 kg) * 5.0 m/s = 30000 kg m/s

The change in momentum of the car-truck system during the collision is:

Δp = p_final - p_car_initial = 30000 kg m/s - 37500 kg m/s = -7500 kg m/s

Since the time interval during which the force is applied is not given in the problem, we cannot calculate the exact values of the forces exerted by the car on the truck and the truck on the car during the collision. However, we know that the forces are equal in magnitude but opposite in direction according to Newton's third law of motion.

Therefore, the force exerted by the car on the truck is equal to 7500 N, and the force exerted by the truck on the car is equal to -7500 N.

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The angular acceleration of the top is 117.81 rad/s^2.

To find the angular acceleration of the top, we can use the formula:
angular acceleration = (final angular velocity - initial angular velocity) / time

We are given that the initial angular velocity is zero (since the top starts from rest) and the final angular velocity is 15.0 rev/s. We need to convert revolutions per second to radians per second, which can be done by multiplying by 2π. So:

final angular velocity = 15.0 rev/s * 2π rad/rev = 94.25 rad/s
The time is given as 0.800 s. Now we can plug these values into the formula:
angular acceleration = (94.25 rad/s - 0 rad/s) / 0.800 s
angular acceleration = 117.81 rad/s^2

Therefore, the angular acceleration of the top is 117.81 rad/s^2.

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If the battery is disconnected and the separation between the plates is increased then the  charge increases and the voltage decreases. Option D

When a parallel-plate capacitor is charged by connection to a battery, it stores electrical energy in the form of separated charges on its plates. If the battery is disconnected and the separation between the plates is increased, the charge on the capacitor remains the same, but the voltage across it decreases.
This is because the capacitance of the capacitor is determined by its geometry, which includes the distance between its plates. When the distance between the plates is increased, the capacitance decreases, and as a result, the voltage across the capacitor also decreases. This is because the charge stored on the plates is spread out over a larger area, reducing the electrical potential difference between them.
It is important to note that the charge on the capacitor remains the same because charges cannot be created or destroyed. They can only be moved around or redistributed. In this case, the charges on the capacitor are simply redistributed over a larger area.
Therefore, the correct answer to the question is option D: the charge increases and the voltage decreases. It is important to understand the relationship between capacitance, charge, and voltage in order to accurately predict the behavior of capacitors in different situations.

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The force exerted by the 5.0-kg mass on the rope when the elevator has an acceleration of 4.0 m/s² upward is 20 N downward. So, the correct answer is option 4.

Newton's second law of motion, which states that the force acting on an object is equal to that object's mass times its acceleration, can be used to ascertain this.

F = ma, where F is the force, m is the object's mass, and an is the lift's acceleration, can be used to determine the force in this situation.

F = (5.0 kg)(4.0 m/s²) = 20 N in this situation.

The mass pulling on the rope is exerting a downward force because the lift is speeding higher.

Therefore, when the lift accelerates at a rate of 4.0 m/s² upward, the force applied to the rope by the 5.0-kg mass is 20 N downward.

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Answer:

Δ M V (change in momentum) = F Δt

The change in momentum (hence the change in velocity) is proportional

to the time that is applied

While standing in a low tunnel, you raise your arms and push against the ceiling with a force of 100 N and mass is 70 kg.

Hence, the correct option is C.

When you push against the ceiling with a force of 100 N, the ceiling exerts an equal and opposite force on you (Newton's third law). This means that the ceiling exerts a force of 100 N on you downwards.

The force that the ceiling exerts on you is also known as the normal force (N) because it is perpendicular to the surface (ceiling) on which you are applying the force.

To calculate the force that the floor exerts on you, we need to consider the forces acting on you in the vertical direction. There are two forces your weight (due to gravity) and the normal force from the floor. When these forces are in equilibrium, you are not accelerating in the vertical direction, i.e. you are at rest.

The weight of you is given by

W = mg

Where W is the weight, m is the mass, and g is the acceleration due to gravity (9.8 m/[tex]s^{2}[/tex]).

W = (70 kg)(9.8 m/[tex]s^{2}[/tex]) = 686 N

W = 686 N

Since you are at rest, the forces in the vertical direction must balance each other out. Therefore, the normal force from the floor must be equal to your weight.

Normal force from floor = W = 686 N

Therefore, the force that the floor exerts on you is 686 N.

Hence, the correct option is C.

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The maximum power this network can dissipate will be 3P/2. The right answer is D.

When two identical resistors are connected in series, their total resistance is 2R.

When a third identical resistor is connected in parallel with these two, the total resistance of the circuit becomes R/3. Using the formula for power,

[tex]P = V^2/R[/tex],

we can calculate the maximum power that each resistor can dissipate as

[tex]P = V^2/R.[/tex]

When two resistors are connected in series, the voltage across them is divided equally.

Therefore, the voltage across each resistor in the series combination is V/2.

When a third resistor is connected in parallel with these two, the voltage across each of the series resistors remains the same (V/2), but the voltage across the parallel resistor is also V/2.

The total power dissipated in the series resistors is

[tex]P1 = (V/2)^2 \times R = V^2/4R.[/tex]

The total power dissipated in the parallel resistor is

[tex]P2 = (V/2)^2 \times (R/3) = V^2/12R.[/tex]

The total power dissipated in the network is the sum of P1 and P2, which is [tex]5V^2/12R[/tex] or 3P/2.

Therefore, the maximum power that this network can dissipate is 3P/2. The right option is D.

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1. For an inelastic collision involving two colliding objects, the following statements are true: 1. Kinetic energy is lost. 2. Momentum is constant.

2. The total momentum of the system remains constant before

and after the collision, as dictated by the conservation of momentum.

1. The following claims are true for an inelastic collision between two objects:

Kinetic energy is lost

Momentum is conserved

Kinetic energy is not gained

Momentum is not lost

Kinetic energy is not constant

Momentum is not gained

Therefore, the correct statements are:

Kinetic energy is lost.

Momentum is conserved.

2. In an inelastic collision, the objects stick together after the collision,

and some of the initial kinetic energy is converted into other forms of

energy, such as heat or deformation.

However, The conservation of momentum requires that the total

momentum of the system be unchanged before and after the collision.

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True . The cutting maneuver, it involves both a decrease in momentum in the original direction of travel and an increase in momentum in the new direction of travel.

1. The cutting maneuver starts with an object (e.g., a vehicle, person, or any moving body) traveling in a certain direction with a given momentum.

2. To change the direction of travel, the object must reduce its momentum in the original direction. This can be achieved by applying a force against the original direction (e.g., braking or turning) to slow down.

3. Once the object's momentum in the original direction is decreased, it must then increase its momentum in the new direction of travel. This is accomplished by applying a force in the desired new direction (e.g., accelerating or pushing off in that direction).

4. As a result, the cutting maneuver successfully transitions the object from its initial direction to the new direction by reducing momentum in the original direction and increasing momentum in the new direction.

In summary, the cutting maneuver requires a decrease in momentum in the original direction of travel and an increase in momentum in the new direction of travel. This is achieved through the application of appropriate forces during the process.

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