Home
Class 12
PHYSICS
A nucelus has binding energy of 100 MeV....

A nucelus has binding energy of `100 MeV`. It further releases `10 MeV` energy. Find the new binding energy of the nucleus.

Text Solution

AI Generated Solution

To solve the problem, we need to understand the concept of binding energy in nuclear physics. The binding energy of a nucleus is the energy required to disassemble the nucleus into its constituent protons and neutrons. A higher binding energy indicates a more stable nucleus. ### Step-by-Step Solution: 1. **Identify the initial binding energy**: The nucleus has an initial binding energy of 100 MeV. 2. **Energy release**: The nucleus releases an additional energy of 10 MeV. This energy release indicates that the nucleus is becoming more stable. ...
Promotional Banner

Topper's Solved these Questions

  • NUCLEAR PHYSICS

    CENGAGE PHYSICS ENGLISH|Exercise Exercise 5.2|27 Videos

  • NUCLEAR PHYSICS

    CENGAGE PHYSICS ENGLISH|Exercise Subjective|35 Videos

  • NUCLEAR PHYSICS

    CENGAGE PHYSICS ENGLISH|Exercise Solved Examples|17 Videos

  • MISCELLANEOUS VOLUME 5

    CENGAGE PHYSICS ENGLISH|Exercise Integer|12 Videos

  • PHOTOELECTRIC EFFECT

    CENGAGE PHYSICS ENGLISH|Exercise Integer Type|4 Videos

Similar Questions

Explore conceptually related problems

Binding energy of a nucleus is.

The value of binding energy per nucleon is

What is binding energy of a satellite?

Nuclear Binding Energy

Define mass defect of a nucleus. Define binding energy of nucleus.

Energy is released in nuclear fission. Total binding energy of the fission fragments is large than the total binding energy of the parent nucleus.

Nucleus ._(3)A^(7) has binding energy per nucleon of 10 MeV . It absorbs a proton and its mass increases by (90)/(100) times the mass of proton. Find the new binding energy of the nucleus so formed. [Take energy equivalent of proton = 930 MeV ]

Binding energy of a nucleus is of the order of:

Consider a nuclear reaction A+B rarr C . A nucleus A moving with kinetic energy of 5 MeV collides with a nucleus B moving with kinetic energy of 3MeV and forms a nucleus C in exicted state. Find the kinetic energy of nucleus C just after its fromation if it is formed in a state with excitation energy 10 MeV . Take masses of nuclei of A,B and C as 25.0,10.0,34.995 amu , respectively. (1amu=930 MeV//c^(2)) .

Consider a nuclear reaction A+B rarr C . A nucleus A moving with kinetic energy of 5 MeV collides with a nucleus B moving with kinetic energy of 3MeV and forms a nucleus C in exicted state. Find the kinetic energy of nucleus C just after its fromation if it is formed in a state with excitation energy 10 MeV . Take masses of nuclei of A,B and C as 25.0,10.0,34.995 amu , respectively. (1amu= 930 MeV//c^(2)) .