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Chapter 6: Q58P (page 280)

The radius of Mars (from the center to just above the atmosphere) is (3400 km $(3400 \times 10^{3} m)$ ), and its mass is $0.6 \times 10^{24} k g$ . An object is launched straight up from just above the atmosphere of Mars. (a) What initial speed is needed so that when the object is far from Mars its final speed is $1000 m / s$ ? (b) What initial speed is needed so that when the object is far from Mars its final speed is $0 m / s$ ? (This is called the escape speed.)

Short Answer

Expert verified

(a) The initial speedwhen the object is far from Marsits final speed is $1000 m / s$ is $4.827 \times 10^{3} m / s$

(b) The initial speed when the object is far from Mars its final speed is 0 m/s is $4.826 \times 10^{3} m / s$

Step by step solution

01

Identification of given data

The radius of Mars is 3400 km
The mass is $0.6 \times 10^{24} k g$
The final speed is $1000 m / s$

02

Definition of the Escape Speed

The Escape Speed is defined as the minimum speed required to break free an object from the gravitational pull of a planet.

03

(a) Calculation of the initial speed when the object is far from Mars its final speed is 1000 m/s

The principle of the conservation of energy is the addition of final kinetic and potential energy is equal to the addition of initial kinetic and potential energy,

The expression will be,

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Most popular questions from this chapter

A runner whose mass is $60 k g$ runs in the $+ x$ direction at a speed of $7 m / s$ . (a) What is the kinetic energy of the runner? (b) Runner turns around and runs in the $- x$ direction at the same speed. Now what is the kinetic energy of the runner?

Figure 6.77 is a graph of the energy of a system of a planet interacting with a star. The gravitational potential energy $U g$ is shown as the thick curve, and plotted along the vertical axis are various values of $K + U g .$

Suppose that $K + U g$ of the system is A. Which of the following statements are true? (a) The potential energy of the system decreases as the planet moves from $r_{1}$ to $r_{2}$ . (b) When the separation between the two bodies is $r_{2}$ , the kinetic energy of the system is $(A - B)$ . (c) The system is a bound system; the planet can never escape. (d) The planet will escape. (e) When the separation between the two bodies is $r_{2}$ , the kinetic energy of the system is (B − C). (f) The kinetic energy of the system is greater when the distance between the star and planet is $r_{1}$ than when the distance between the two bodies is $r_{2}$ .

Suppose instead that $K + U g$ of the system is B. Which of the following statements are true? (a) When the separation between the planet and star is $r_{2}$ , the kinetic energy of the system is zero. (b) The planet and star cannot get farther apart than $r_{2}$ . (c) This is not a bound system; the planet can escape. (d) When the separation between the planet and star is $r_{2}$ , the potential energy of the system is zero.

You pull a block of mass macross a frictionless table with a constant force. You also pull with an equal constant force a block of larger mass M. The blocks are initially at rest. If you pull the blocks through the same distance, which block has the greater kinetic energy, and which block has the greater momentum? If instead you pull the blocks for the same amount of time, which block has the greater kinetic energy, and which block has the greater momentum?

The point of this question is to compare rest energy and kinetic energy at high speeds. An alpha particle (a helium nucleus) is moving at a speed of $0.9993$ times the speed of light. Its mass is $6.40 \times 10^{- 27} k g$ (a) what is its rest energy? (b) Is it okay to calculate its kinetic energy using the expression $K - \frac{1}{2} m v^{2}$ ?(c) What is its kinetic energy? (d) Which is true? A. the kinetic energy is approximately equal to the rest energy. B. The kinetic energy is much bigger than the rest energy. C. The kinetic energy is much smaller than the rest energy.

A proton $({}^{1}H)$ and a deuteron ( $({}^{2}H)$ , “heavy” hydrogen) start out far apart. An experimental apparatus shoots them toward each other (with equal and opposite momenta). If they get close enough to make actual contact with each other, they can react to form a helium-3nucleus and a gamma ray (a high-energy photon, which has kinetic energy but zero rest energy): ${}^{1}H +^{2} H \to^{3} He + y$

This is one of the thermonuclear or fusion reactions that takes place inside a star such as our Sun.

The mass of the proton is 1.0073 u(unified atomic mass unit, $1.7 \times 10^{- 27} kg$ ), the mass of the deuteron is 2.0136 u, the mass of the helium-3nucleus is 3.0155 u, and the gamma ray is massless. Although in most problems you solve in this course it is adequate to use values of constants rounded to two or three significant figures, in this problem you must keep at least six significant figures throughout your calculation. Problems involving mass changes require many significant figures because the changes in mass are small compared to the total mass. (a) The strong interaction has a very short range and is essentially a contact interaction. For this fusion reaction to take place, the proton and deuteron have to come close enough together to touch. The approximate radius of a proton or neutron is about $1 \times 10^{- 15} m$ . What is the approximate initial total kinetic energy of the proton and deuteron required for the fusion reaction to proceed, in joules and electron volts ( $1 eV = 1.6 \times 10^{- 19} J$ )? (b) Given the initial conditions found in part (a), what is the kinetic energy of the ${}^{3}{He}$ plus the energy of the gamma ray, in joules and in electron volts? (c) The net energy released is the kinetic energy of the ${}^{3}{He}$ plus the energy of the gamma ray found in part (b), minus the energy input that you calculated in part (a). What is the net energy release, in joules and in electron volts? Note that you do get back the energy investment made in part (a). (d) Kinetic energy can be used to drive motors and do other useful things. If a mole of hydrogen and a mole of deuterium underwent this fusion reaction, how much kinetic energy would be generated? (For comparison, aroundare obtained from burning a mole of gasoline.) (e) Which of the following potential energy curvesin Figure 6.87 is a reasonable representation of the interaction in this fusion reaction? Why?

As we will study later, the average kinetic energy of a gas molecule is $\frac{3}{2} k_{b} T$ , whereis the “Boltzmann constant,” $1.4 \times 10^{- 23} J / K$ , andis the absolute or Kelvin temperature, measured from absolute zero (so that the freezing point of water is $273 K$ ). The approximate temperature required for the fusion reaction to proceed is very high. This high temperature, required because of the electric repulsion barrier to the reaction, is the main reason why it has been so difficult to make progress toward thermonuclear power generation. Sufficiently high temperatures are found in the interior of the Sun, where fusion reactions take place.

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