The compound unstabel nucleus `._(92)^(236)U` often decays in accordance with the following reaction `._(92)^(236)U rarr ._(54)^(140)Xe +._(38)^(94)Sr ` + other particles During the reaction, the uranium nucleus 'fissions' (splits) into the two smaller nuceli have higher nuclear binding energy per nucleon (although the lighter nuclei have lower total nuclear binding energies, because they contain fewer nucleons). Inside a nucleus, the nucleons (protonsa and neutrons)attract each other with a 'strong nuclear' force. All neutrons exert approxiamtely the same strong nuclear force on each other. This force holds the nuclear are very close together at intranuclear distances. A proton and a neutron are both shot at `100 m s^(-1)` toward a `._6^(12)C` nuleus. Which partilce, if either, is more likely to be absorebed by the nucleus?A. The protonB. The neutronC. Both particles are about equally likely to be absorbed,.D. Neither particle will be absorbed.

The compound unstabel nucleus `._(92)^(236)U` often decays in accordan

1.	The compound unstabel nucleus `._(92)^(236)U` often decays in accordance with the following reaction `._(92)^(236)U rarr ._(54)^(140)Xe +._(38)^(94)Sr ` + other particles During the reaction, the uranium nucleus 'fissions' (splits) into the two smaller nuceli have higher nuclear binding energy per nucleon (although the lighter nuclei have lower total nuclear binding energies, because they contain fewer nucleons). Inside a nucleus, the nucleons (protonsa and neutrons)attract each other with a 'strong nuclear' force. All neutrons exert approxiamtely the same strong nuclear force on each other. This force holds the nuclear are very close together at intranuclear distances. A proton and a neutron are both shot at `100 m s^(-1)` toward a `._6^(12)C` nuleus. Which partilce, if either, is more likely to be absorebed by the nucleus?A. The protonB. The neutronC. Both particles are about equally likely to be absorbed,.D. Neither particle will be absorbed.
Answer» Correct Answer - b Once the neutron gets sufficiently close to the nucleus, the strong nuclear froces sucks it in. Same happens with the proton except it is electrostatically repelled by the six protons already inside the carbon nucleus. The repulsiohn prevents a `100 ms^(-1)` proton from getting close enough to the nucleus. Therefore, the answer is (b).

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