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Chapter 4: Problem 64

A particle of mass \(5 \mathrm{~kg}\) moving in the \(X-Y\) plane has its potential energy given by \(U=(-7 x+24 y)\) Joule. The particle is initially at origin and has velocity \(\vec{u}=(14.4 \hat{i}+4.2 \hat{j}) \mathrm{m} / \mathrm{s}\) (A) The particle has speed \(25 \mathrm{~m} / \mathrm{s}\) at \(t=4 \mathrm{~s}\). (B) The particle has an acceleration \(5 \mathrm{~m} / \mathrm{s}^{2}\). (C) The acceleration of particle is normal at its initial velocity. (D) None of these.

Short Answer

Expert verified
The correct answer is (D) None of these.

Step by step solution

01

Calculate the force from the potential energy function

To find the force in both the x and y directions, we can use the negative gradient of the potential energy function: \(F_x = -\frac{dU}{dx}\) and \(F_y = -\frac{dU}{dy}\) The potential energy function U is given by: \(U = -7x + 24y\) To find the force components, we will differentiate U with respect to x and y, and then find the negative of these values: \(F_x = -\frac{dU}{dx} = -\frac{-7}{dx} = 7 \mathrm{N}\) \(F_y = -\frac{dU}{dy} = -\frac{24}{dy} = -24 \mathrm{N}\)
02

Calculate the acceleration from the force and mass

Now we are given the mass of the particle, which is m = 5 kg. We can use Newton's second law, \(F = ma\), to calculate the acceleration components in the x and y directions: \(a_x = \frac{F_x}{m} = \frac{7}{5} \mathrm{m/s^2}\) \(a_y = \frac{F_y}{m} = \frac{-24}{5} \mathrm{m/s^2}\) Thus, the acceleration vector is \(\vec{a} = (\frac{7}{5}\hat{i} - \frac{24}{5}\hat{j}) \mathrm{m/s^2}\).
03

Check the given options

(A) We need to find the speed of the particle at t = 4 s. First, we have to find the velocity vector at 4 s and then calculate its magnitude to determine if it's 25 m/s. The velocity at t can be calculated as: \(\vec{v}(t) = \vec{u} + \vec{a}t\) At t = 4 s: \(\vec{v}(4) = (14.4\hat{i} + 4.2\hat{j}) + (\frac{7}{5}\hat{i} - \frac{24}{5}\hat{j}) \times 4\) \(\vec{v}(4) = (14.4 + \frac{28}{5})\hat{i} + (4.2 - \frac{96}{5})\hat{j}\) Speed: \(|v(4)| = \sqrt{(\vec{v}_x(4))^2 + (\vec{v}_y(4))^2} \ne 25 \mathrm{m/s}\) So, option (A) is false. (B) To check if the particle has an acceleration of 5 m/s², we can find the magnitude of the acceleration vector: \(a = |\vec{a}| = \sqrt{(a_x)^2 + (a_y)^2} \ne 5 \mathrm{m/s^2}\) So, option (B) is false. (C) To check if the acceleration is normal to the initial velocity, we can find the dot product of the velocity and acceleration vectors: \(\vec{u} \cdot \vec{a} = (14.4 \hat{i} + 4.2 \hat{j}) \cdot (\frac{7}{5}\hat{i} - \frac{24}{5}\hat{j})\) \(\vec{u} \cdot \vec{a} = 14.4 \times \frac{7}{5} + 4.2 \times \frac{-24}{5}\) \(\vec{u} \cdot \vec{a} \ne 0\) Since the dot product of the initial velocity and acceleration is not equal to 0, the acceleration is not normal to the initial velocity. So, option (C) is false. Since all options (A), (B), and (C) are false, the correct answer is (D) None of these.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

JEE Main Physics
In JEE Main Physics, understanding the interplay of force, motion, and energy is crucial. One must comprehend how to apply the concepts to solve problems frequently, involving calculations of force and motion. Can a particle adhere to Newton's laws of motion under certain potential energy conditions? Solving such problems requires not only formula memorization but also a deep understanding of underlying principles.

For JEE aspirants, the exercise given illustrates an application of potential energy concepts and Newton's second law to find a particle's motion parameters. Students need to interpret the potential energy function and translate it into forces acting on the particle, and subsequently its acceleration. By solving these kinds of problems, students enhance their problem-solving skills critical to excel in JEE Main Physics.
Potential energy function
The potential energy function describes the energy stored in a system due to its position or configuration. In this exercise, the particle's potential energy in the X-Y plane is given as a function of its coordinates. The ability to derive forces from this potential energy function is essential. By taking the negative gradient, you obtain the force vector, which directs the particle's motion.

This concept is pivotal because forces dictate the motion of objects, and in physics problems, we're often asked to predict the behavior of objects when subjected to these forces. In the context of JEE Main problems, a correct interpretation of potential energy functions, like the one provided in this exercise, serves as a fundamental step towards arriving at the correct answers.
Newton's second law of motion
Newton's second law of motion states that the force acting on an object is equal to the mass of the object multiplied by its acceleration (\( F = ma \)). When presented with a physics problem, understanding this law is crucial as it relates the calculated forces to the resulting accelerations. In this particular problem, after calculating the forces from the potential energy function, we applied this second law to find the particle's acceleration.

By mastering Newton's second law, students can predict how the velocity of an object changes over time, which is a fundamental aspect of solving kinetic and dynamic problems. As shown in the exercise, knowing the initial conditions such as the mass of a particle and the forces acting on it allows you to calculate this object's future state using Newton's principles. This is an essential skill for tackling physics problems in the JEE.

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Most popular questions from this chapter

We generally ignore the kinetic energy of the moving coil of a spring but consider a spring of mass \(m\), equilibrium length \(L\) and spring constant \(k\). Consider a spring, as described above, that has one end fixed and the other end moving with speed \(v .\) Assume that the speed of points along the length of the spring varies linearly with distance \(L\) from the fixed end. Assume also that the mass \(m\) of the spring is distributed uniformly along the length of the spring. Assume further that the force applied by the spring is spring constant times its deformation. In a spring gun, such a spring of mass \(0.243 \mathrm{~kg}\) and force constant \(3200 \mathrm{~N} / \mathrm{m}\) is compressed \(2.50 \mathrm{~cm}\) from its unstretched length. When the trigger is pulled, the spring pushes horizontally the ball of mass of \(0.053 \mathrm{~kg}\). Ball's speed when the spring reaches its uncompressed length is (A) \(3.9 \mathrm{~m} / \mathrm{s}\) (B) \(6.1 \mathrm{~m} / \mathrm{s}\) (C) \(14 \mathrm{~m} / \mathrm{s}\) (D) \(1.62 \mathrm{~m} / \mathrm{s}\)

Two springs have force constants, \(K_{1}\) and \(K_{2}\left(K_{1}>K_{2}\right)\) The work done, when both are stretched by the same amount of length will be (A) Equal (B) Greater for \(K_{1}\) (C) Greater for \(K_{2}\) (D) Given data is incomplete

A body of mass \(m\) accelerates uniformly from rest to \(v_{1}\) in time \(t_{1}\). The instantaneous power delivered to the body as a function of time \(t\) is [2004] (A) \(\frac{m v_{1} t^{2}}{t_{1}}\) (B) \(\frac{m v_{1}^{2} t}{t_{1}^{2}}\) (C) \(\frac{m v_{1} t}{t_{1}}\) (D) \(\frac{m v_{1}^{2} t}{t_{1}}\)

A bicyclist comes to a skidding stop in \(10 \mathrm{~m}\). During this process, the force on the bicycle due to the road is \(200 \mathrm{~N}\) and is directly opposed to the motion. The work done by the cycle on the road is \((\mathrm{A})+2000 \mathrm{~J}\) (B) \(-200 \mathrm{~J}\) (C) Zero (D) \(-20,000 \mathrm{~J}\)

A person trying to lose weight, lifts a \(10 \mathrm{~kg}\) mass \(0.5 \mathrm{~m}\), 1000 times daily. Fat supplies \(4 \times 10^{7} \mathrm{~J}\) of energy per kilogram which is converted into potential energy to raise the weight with \(20 \%\) efficiency rate. The potential energy lost each time the person lowers the mass is dissipated \(\left(g=10 \mathrm{~m} / \mathrm{s}^{2}\right)\) How much work does the person do against the gravitational force daily? (A) \(25 \mathrm{~kJ}\) (B) \(50 \mathrm{~kJ}\) (C) \(10 \mathrm{~kJ}\) (D) \(75 \mathrm{~kJ}\)
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