4 m may be greater than, less than or equal to $\mathrm{Zm}_{\mathrm{p}}+\mathrm{Nm}_{\mathrm{n}}$, depending on nature of element
Explanation:
C Given, $M_{p}$ and $M_{n}$ are masses of proton and neutron We know that the atomic mass (m) of any stable nucleus is always less than the sum of the masses of constituent particle $\mathrm{m} \lt \left(\mathrm{Z}_{\mathrm{m}_{\mathrm{p}}}+\mathrm{N}_{\mathrm{m}_{\mathrm{n}}}\right)$
AIPMT- 2001
NUCLEAR PHYSICS
147423
The nuclei ${ }_{6} \mathrm{C}^{13}$ and ${ }_{7} \mathrm{~N}^{14}$ can be described as
1 Isotones
2 Isobars
3 Isotopes of carbon
4 Isotopes of nitrogen
Explanation:
A The nuclei ${ }_{6} \mathrm{C}^{13}$ and ${ }_{7} \mathrm{~N}^{14}$ is a isotones means same number of neutrons ${ }_{6} \mathrm{C}^{13}$ number of neutrons $=13-6=7$ ${ }_{7} \mathrm{~N}^{14}$ number of neutrons $=14-7=7$ Both have the same number of neutrons so they are isotones.
AIPMT- 1990
NUCLEAR PHYSICS
147437
When two deuterium nuclei fuse together to form tritium, we get a
1 neutron
2 proton
3 $\alpha$-particle
4 deuteron
Explanation:
B Nuclear reaction is, $2 \underset{\text { (Deuterium) }}{\mathrm{H}^{2}} \rightarrow \underset{\text { (Tritium) }}{1} \mathrm{H}^{3}+\underset{\text { (Proton) }}{{ }_{1} \mathrm{H}^{1}}$ Hence, from the above reaction, we get proton.
4 m may be greater than, less than or equal to $\mathrm{Zm}_{\mathrm{p}}+\mathrm{Nm}_{\mathrm{n}}$, depending on nature of element
Explanation:
C Given, $M_{p}$ and $M_{n}$ are masses of proton and neutron We know that the atomic mass (m) of any stable nucleus is always less than the sum of the masses of constituent particle $\mathrm{m} \lt \left(\mathrm{Z}_{\mathrm{m}_{\mathrm{p}}}+\mathrm{N}_{\mathrm{m}_{\mathrm{n}}}\right)$
AIPMT- 2001
NUCLEAR PHYSICS
147423
The nuclei ${ }_{6} \mathrm{C}^{13}$ and ${ }_{7} \mathrm{~N}^{14}$ can be described as
1 Isotones
2 Isobars
3 Isotopes of carbon
4 Isotopes of nitrogen
Explanation:
A The nuclei ${ }_{6} \mathrm{C}^{13}$ and ${ }_{7} \mathrm{~N}^{14}$ is a isotones means same number of neutrons ${ }_{6} \mathrm{C}^{13}$ number of neutrons $=13-6=7$ ${ }_{7} \mathrm{~N}^{14}$ number of neutrons $=14-7=7$ Both have the same number of neutrons so they are isotones.
AIPMT- 1990
NUCLEAR PHYSICS
147437
When two deuterium nuclei fuse together to form tritium, we get a
1 neutron
2 proton
3 $\alpha$-particle
4 deuteron
Explanation:
B Nuclear reaction is, $2 \underset{\text { (Deuterium) }}{\mathrm{H}^{2}} \rightarrow \underset{\text { (Tritium) }}{1} \mathrm{H}^{3}+\underset{\text { (Proton) }}{{ }_{1} \mathrm{H}^{1}}$ Hence, from the above reaction, we get proton.
4 m may be greater than, less than or equal to $\mathrm{Zm}_{\mathrm{p}}+\mathrm{Nm}_{\mathrm{n}}$, depending on nature of element
Explanation:
C Given, $M_{p}$ and $M_{n}$ are masses of proton and neutron We know that the atomic mass (m) of any stable nucleus is always less than the sum of the masses of constituent particle $\mathrm{m} \lt \left(\mathrm{Z}_{\mathrm{m}_{\mathrm{p}}}+\mathrm{N}_{\mathrm{m}_{\mathrm{n}}}\right)$
AIPMT- 2001
NUCLEAR PHYSICS
147423
The nuclei ${ }_{6} \mathrm{C}^{13}$ and ${ }_{7} \mathrm{~N}^{14}$ can be described as
1 Isotones
2 Isobars
3 Isotopes of carbon
4 Isotopes of nitrogen
Explanation:
A The nuclei ${ }_{6} \mathrm{C}^{13}$ and ${ }_{7} \mathrm{~N}^{14}$ is a isotones means same number of neutrons ${ }_{6} \mathrm{C}^{13}$ number of neutrons $=13-6=7$ ${ }_{7} \mathrm{~N}^{14}$ number of neutrons $=14-7=7$ Both have the same number of neutrons so they are isotones.
AIPMT- 1990
NUCLEAR PHYSICS
147437
When two deuterium nuclei fuse together to form tritium, we get a
1 neutron
2 proton
3 $\alpha$-particle
4 deuteron
Explanation:
B Nuclear reaction is, $2 \underset{\text { (Deuterium) }}{\mathrm{H}^{2}} \rightarrow \underset{\text { (Tritium) }}{1} \mathrm{H}^{3}+\underset{\text { (Proton) }}{{ }_{1} \mathrm{H}^{1}}$ Hence, from the above reaction, we get proton.
4 m may be greater than, less than or equal to $\mathrm{Zm}_{\mathrm{p}}+\mathrm{Nm}_{\mathrm{n}}$, depending on nature of element
Explanation:
C Given, $M_{p}$ and $M_{n}$ are masses of proton and neutron We know that the atomic mass (m) of any stable nucleus is always less than the sum of the masses of constituent particle $\mathrm{m} \lt \left(\mathrm{Z}_{\mathrm{m}_{\mathrm{p}}}+\mathrm{N}_{\mathrm{m}_{\mathrm{n}}}\right)$
AIPMT- 2001
NUCLEAR PHYSICS
147423
The nuclei ${ }_{6} \mathrm{C}^{13}$ and ${ }_{7} \mathrm{~N}^{14}$ can be described as
1 Isotones
2 Isobars
3 Isotopes of carbon
4 Isotopes of nitrogen
Explanation:
A The nuclei ${ }_{6} \mathrm{C}^{13}$ and ${ }_{7} \mathrm{~N}^{14}$ is a isotones means same number of neutrons ${ }_{6} \mathrm{C}^{13}$ number of neutrons $=13-6=7$ ${ }_{7} \mathrm{~N}^{14}$ number of neutrons $=14-7=7$ Both have the same number of neutrons so they are isotones.
AIPMT- 1990
NUCLEAR PHYSICS
147437
When two deuterium nuclei fuse together to form tritium, we get a
1 neutron
2 proton
3 $\alpha$-particle
4 deuteron
Explanation:
B Nuclear reaction is, $2 \underset{\text { (Deuterium) }}{\mathrm{H}^{2}} \rightarrow \underset{\text { (Tritium) }}{1} \mathrm{H}^{3}+\underset{\text { (Proton) }}{{ }_{1} \mathrm{H}^{1}}$ Hence, from the above reaction, we get proton.