Noble gases have large positive electron gain enthalpies since, they have no tendency to accept electron due to stable configuration.
JEE - 2023
CHXI11:THE P-BLOCK ELEMENTS
316413
Due to stable electronic configurations I. These gases exhibit very high ionisation enthalpy II. These have no tendency to accept the electron. III. These have large positive values of electron gain enthalpy. The incorrect set of statements is
1 I, II and III
2 I and II
3 II and III
4 None of these
Explanation:
Due to stable electronic configurations, these gases exhibit very high ionisation enthalpy. They have no tendency to accept the electron and therefore, have large positive values of electron gain enthalpy.
CHXI11:THE P-BLOCK ELEMENTS
316414
Atomic radii of fluorine and neon in Angstrom units are respectively given by
1 \(0.72 ; 1.60\)
2 \(1.60 ; 1.60\)
3 \(0.72 ; 0.72\)
4 None
Explanation:
In inert gases we have van der Waals radii which is always higher than atomic radii.
CHXI11:THE P-BLOCK ELEMENTS
316415
Noble gases have very low boiling points because
1 Interatomic forces are negligible
2 Interatomic forces are stronger
3 They are inert
4 They have completely filled valency shell
Explanation:
Noble gases being monoatomic have no interatomic forces except weak dispersion forces and therefore, they are liquefied at very low temperatures. Hence, they have low boiling points.
CHXI11:THE P-BLOCK ELEMENTS
316416
The forces acting between noble gas atoms are:
1 Van der waal's forces
2 Ion-dipole forces
3 London-dispersion forces
4 Magnetic forces
Explanation:
Atoms of noble gases are held together by weak van der waal's force of attraction.
Noble gases have large positive electron gain enthalpies since, they have no tendency to accept electron due to stable configuration.
JEE - 2023
CHXI11:THE P-BLOCK ELEMENTS
316413
Due to stable electronic configurations I. These gases exhibit very high ionisation enthalpy II. These have no tendency to accept the electron. III. These have large positive values of electron gain enthalpy. The incorrect set of statements is
1 I, II and III
2 I and II
3 II and III
4 None of these
Explanation:
Due to stable electronic configurations, these gases exhibit very high ionisation enthalpy. They have no tendency to accept the electron and therefore, have large positive values of electron gain enthalpy.
CHXI11:THE P-BLOCK ELEMENTS
316414
Atomic radii of fluorine and neon in Angstrom units are respectively given by
1 \(0.72 ; 1.60\)
2 \(1.60 ; 1.60\)
3 \(0.72 ; 0.72\)
4 None
Explanation:
In inert gases we have van der Waals radii which is always higher than atomic radii.
CHXI11:THE P-BLOCK ELEMENTS
316415
Noble gases have very low boiling points because
1 Interatomic forces are negligible
2 Interatomic forces are stronger
3 They are inert
4 They have completely filled valency shell
Explanation:
Noble gases being monoatomic have no interatomic forces except weak dispersion forces and therefore, they are liquefied at very low temperatures. Hence, they have low boiling points.
CHXI11:THE P-BLOCK ELEMENTS
316416
The forces acting between noble gas atoms are:
1 Van der waal's forces
2 Ion-dipole forces
3 London-dispersion forces
4 Magnetic forces
Explanation:
Atoms of noble gases are held together by weak van der waal's force of attraction.
Noble gases have large positive electron gain enthalpies since, they have no tendency to accept electron due to stable configuration.
JEE - 2023
CHXI11:THE P-BLOCK ELEMENTS
316413
Due to stable electronic configurations I. These gases exhibit very high ionisation enthalpy II. These have no tendency to accept the electron. III. These have large positive values of electron gain enthalpy. The incorrect set of statements is
1 I, II and III
2 I and II
3 II and III
4 None of these
Explanation:
Due to stable electronic configurations, these gases exhibit very high ionisation enthalpy. They have no tendency to accept the electron and therefore, have large positive values of electron gain enthalpy.
CHXI11:THE P-BLOCK ELEMENTS
316414
Atomic radii of fluorine and neon in Angstrom units are respectively given by
1 \(0.72 ; 1.60\)
2 \(1.60 ; 1.60\)
3 \(0.72 ; 0.72\)
4 None
Explanation:
In inert gases we have van der Waals radii which is always higher than atomic radii.
CHXI11:THE P-BLOCK ELEMENTS
316415
Noble gases have very low boiling points because
1 Interatomic forces are negligible
2 Interatomic forces are stronger
3 They are inert
4 They have completely filled valency shell
Explanation:
Noble gases being monoatomic have no interatomic forces except weak dispersion forces and therefore, they are liquefied at very low temperatures. Hence, they have low boiling points.
CHXI11:THE P-BLOCK ELEMENTS
316416
The forces acting between noble gas atoms are:
1 Van der waal's forces
2 Ion-dipole forces
3 London-dispersion forces
4 Magnetic forces
Explanation:
Atoms of noble gases are held together by weak van der waal's force of attraction.
Noble gases have large positive electron gain enthalpies since, they have no tendency to accept electron due to stable configuration.
JEE - 2023
CHXI11:THE P-BLOCK ELEMENTS
316413
Due to stable electronic configurations I. These gases exhibit very high ionisation enthalpy II. These have no tendency to accept the electron. III. These have large positive values of electron gain enthalpy. The incorrect set of statements is
1 I, II and III
2 I and II
3 II and III
4 None of these
Explanation:
Due to stable electronic configurations, these gases exhibit very high ionisation enthalpy. They have no tendency to accept the electron and therefore, have large positive values of electron gain enthalpy.
CHXI11:THE P-BLOCK ELEMENTS
316414
Atomic radii of fluorine and neon in Angstrom units are respectively given by
1 \(0.72 ; 1.60\)
2 \(1.60 ; 1.60\)
3 \(0.72 ; 0.72\)
4 None
Explanation:
In inert gases we have van der Waals radii which is always higher than atomic radii.
CHXI11:THE P-BLOCK ELEMENTS
316415
Noble gases have very low boiling points because
1 Interatomic forces are negligible
2 Interatomic forces are stronger
3 They are inert
4 They have completely filled valency shell
Explanation:
Noble gases being monoatomic have no interatomic forces except weak dispersion forces and therefore, they are liquefied at very low temperatures. Hence, they have low boiling points.
CHXI11:THE P-BLOCK ELEMENTS
316416
The forces acting between noble gas atoms are:
1 Van der waal's forces
2 Ion-dipole forces
3 London-dispersion forces
4 Magnetic forces
Explanation:
Atoms of noble gases are held together by weak van der waal's force of attraction.
Noble gases have large positive electron gain enthalpies since, they have no tendency to accept electron due to stable configuration.
JEE - 2023
CHXI11:THE P-BLOCK ELEMENTS
316413
Due to stable electronic configurations I. These gases exhibit very high ionisation enthalpy II. These have no tendency to accept the electron. III. These have large positive values of electron gain enthalpy. The incorrect set of statements is
1 I, II and III
2 I and II
3 II and III
4 None of these
Explanation:
Due to stable electronic configurations, these gases exhibit very high ionisation enthalpy. They have no tendency to accept the electron and therefore, have large positive values of electron gain enthalpy.
CHXI11:THE P-BLOCK ELEMENTS
316414
Atomic radii of fluorine and neon in Angstrom units are respectively given by
1 \(0.72 ; 1.60\)
2 \(1.60 ; 1.60\)
3 \(0.72 ; 0.72\)
4 None
Explanation:
In inert gases we have van der Waals radii which is always higher than atomic radii.
CHXI11:THE P-BLOCK ELEMENTS
316415
Noble gases have very low boiling points because
1 Interatomic forces are negligible
2 Interatomic forces are stronger
3 They are inert
4 They have completely filled valency shell
Explanation:
Noble gases being monoatomic have no interatomic forces except weak dispersion forces and therefore, they are liquefied at very low temperatures. Hence, they have low boiling points.
CHXI11:THE P-BLOCK ELEMENTS
316416
The forces acting between noble gas atoms are:
1 Van der waal's forces
2 Ion-dipole forces
3 London-dispersion forces
4 Magnetic forces
Explanation:
Atoms of noble gases are held together by weak van der waal's force of attraction.
