/*! This file is auto-generated */ .wp-block-button__link{color:#fff;background-color:#32373c;border-radius:9999px;box-shadow:none;text-decoration:none;padding:calc(.667em + 2px) calc(1.333em + 2px);font-size:1.125em}.wp-block-file__button{background:#32373c;color:#fff;text-decoration:none} Problem 84 The ratio of the radii of the pl... [FREE SOLUTION] | 91Ó°ÊÓ

91Ó°ÊÓ

Log out

Learning Materials

Features

Discover

Chapter 10: Problem 84

The ratio of the radii of the planets \(P_{1}\) and \(P_{2}\) is \(a\). The ratio of their acceleration due to gravity is \(b .\) The ratio of the escape velocities from them will be (a) \(a b\) (b) \(\sqrt{a b}\) (c) \(\sqrt{a / b}\) (d) \(\sqrt{b / a}\)

Short Answer

Expert verified
The ratio of the escape velocities is \(\sqrt{ab}\), option (b).

Step by step solution

01

Understanding Given Ratios

We know the ratio of the radii of planets \(P_1\) and \(P_2\) is \(a\), meaning \(\frac{R_1}{R_2} = a\). The ratio of the acceleration due to gravity is \(b\), meaning \(\frac{g_1}{g_2} = b\). We need to derive the formula for the ratio of escape velocities.
02

Escape Velocity Formula

The escape velocity \(v_e\) from a planet is given by the formula:\[v_e = \sqrt{2gR}\].This means the escape velocity for \(P_1\) is \(v_{e1} = \sqrt{2g_1R_1}\) and for \(P_2\) is \(v_{e2} = \sqrt{2g_2R_2}\).
03

Setting Up the Ratio for Escape Velocities

The ratio of escape velocities \(\frac{v_{e1}}{v_{e2}}\) is given by:\[\frac{v_{e1}}{v_{e2}} = \frac{\sqrt{2g_1R_1}}{\sqrt{2g_2R_2}} = \sqrt{\frac{g_1R_1}{g_2R_2}}\].
04

Substituting Known Ratios

Substitute the known ratios \(\frac{g_1}{g_2} = b\) and \(\frac{R_1}{R_2} = a\) into the escape velocity ratio:\[\sqrt{\frac{g_1R_1}{g_2R_2}} = \sqrt{\frac{g_1}{g_2} \cdot \frac{R_1}{R_2}} = \sqrt{b \cdot a}\].
05

Conclusion

Thus, the ratio of the escape velocities from the planets \(P_1\) and \(P_2\) is \(\sqrt{ab}\). Hence, the correct answer is option (b).

Unlock Step-by-Step Solutions & Ace Your Exams!

  • Full Textbook Solutions

    Get detailed explanations and key concepts

  • Unlimited Al creation

    Al flashcards, explanations, exams and more...

  • Ads-free access

    To over 500 millions flashcards

  • Money-back guarantee

    We refund you if you fail your exam.

Over 30 million students worldwide already upgrade their learning with 91Ó°ÊÓ!

Key Concepts

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

Acceleration Due to Gravity
Acceleration due to gravity is a fundamental force that pulls objects towards the center of a planet. This force is unique for each celestial body and usually represented by the symbol \(g\). It varies based on several factors:
  • The mass of the planet: Larger masses generate stronger gravitational forces.
  • The radius of the planet: Gravity is inversely proportional to the square of the radius.
To understand how gravity differs between two planets, if planet \(P_1\) has a ratio \(b\) times the gravity of planet \(P_2\), it tells us how the force pulling objects down on each planet compares. This ratio plays a crucial role when calculating escape velocities, as seen later.
Planetary Radii
Planetary radii determine several dynamical properties of a planet, including its gravitational force and escape velocity. The radius \(R\) is the distance from the planet's center to its surface. When comparing two planets such as \(P_1\) and \(P_2\), the ratio of their radii \(a = \frac{R_1}{R_2}\) helps understand their relative sizes.
  • A larger radius would suggest more surface area from which gravity acts.
  • A smaller radius generally implies a stronger surface gravity, assuming similar masses.
Thus, understanding planetary radii can aid in comparing the escape velocities of different celestial bodies, as it directly influences the gravitational energy potential needed to escape a planet's gravitational pull.
Velocity Ratio
The velocity ratio between two planets is pivotal in determining how fast an object must travel to escape from the gravitational pull of each planet.
Escape velocity \(v_e\) is derived from the principles of gravitational force and is defined by the formula \(v_e = \sqrt{2gR}\). This incorporates both the acceleration due to gravity \(g\) and the planetary radius \(R\).
  • The ratio of escape velocities \(\frac{v_{e1}}{v_{e2}}\) for two planets shows how diverging parameters like gravity and size affect their gravitational thresholds.
  • In the exercise, substituting \(\frac{g_1}{g_2} = b\) and \(\frac{R_1}{R_2} = a\) into the equation gives us the velocity ratio as \(\sqrt{ab}\).
Therefore, the ratio \(\sqrt{ab}\) reveals the relationship of gravitational forces and physical dimensions between planets, directly impacting what speed is required for space travel from each one.

One App. One Place for Learning.

All the tools & learning materials you need for study success - in one app.

Get started for free

Most popular questions from this chapter

A straight rod of length \(L\) extends from \(x=a\) to \(x=L+a\). Find the gravitational force it, exerts on a point mass \(m\) at \(x=0\) if the linear density of rod \(\mu=A+B x^{2}\) (a) \(\mathrm{Gm}\left[\frac{A}{\mathrm{a}}+\mathrm{BL}\right]\) (b) \(G m\left[A\left(\frac{1}{a}-\frac{1}{a+L}\right)+B L\right]\) (c) \(G m\left[B L+\frac{A}{a+L}\right]\) (d) \(G m\left[B L-\frac{A}{a}\right]\)

When a person is high up on the ladder. Then a large torque is produced due to his weight about the point of contact between the ladder and the floor whereas when he starts climbing up the torque is small, Due to this reason the ladder is more opt to slip when one is high up on it.

A thief stole a box full of valuable articles of weight \(w\) and while carrying it on his head jumped down from a wall of height \(h\) from the ground. Before he reaches the ground, he experienced a load (a) zero (b) \(w / 2\) (c) \(w\) (d) \(2 w\)

A particle of mass \(m\) is placed at the centre of a uniform spherical shell of mass \(3 \mathrm{~m}\) and radius \(R\). The gravitational potential on the surface of the shell is (a) \(-\frac{G m}{R}\) (b) \(-\frac{3 \mathrm{Gm}}{R}\) (c) \(-\frac{4 G m}{R}\) (d) \(-\frac{2 G m}{R}\)

A satellite \(S\) is moving in an elliptical orbit around earth. The mass of the satellite is very small compared to the mass of the earth? (a) The acceleration of \(S\) is always directed towards the centre of the earth (b) The angular momentum of \(S\) about the centre of the earth changes in direction but its magnitude remains constant (c) The total mechanical energy of \(S\) varies periodically with time (d) The linear momentum of \(S\) remains constant in magnitude
See all solutions

Recommended explanations on Physics Textbooks

Classical Mechanics

Read Explanation

Measurements

Read Explanation

Space Physics

Read Explanation

Kinematics Physics

Read Explanation

Electromagnetism

Read Explanation

Thermodynamics

Read Explanation
View all explanations

What do you think about this solution?

We value your feedback to improve our textbook solutions.

Study anywhere. Anytime. Across all devices.