Boron has lesser ionization enthalpy than Beryllium, because:
1. | It is easier to remove electrons from p - a subshell than a filled s - subshell. |
2. | The s-electron can be removed easier than the p-electron. |
3. | Ionization enthalpy decreases with an increase in atomic number. |
4. | Ionization enthalpy increases along the period. |
A configuration with the lowest ionization enthalpy among the following is:
1. \(1 s^2 2 s^2 2 p^5\)
2. \(1 s^2 2 s^2 2 p^3\)
3. \(1 s^2 2 s^2 2 p^6 3 s^1\)
4. \(1 s^2 2 s^2 2 p^6\)
The incorrect statement about ionization enthalpy is:
1. | Ionization enthalpy increases for each successive electron. |
2. | Noble gases have the highest ionization enthalpy. |
3. | A big jump in ionization enthalpy indicates a stable configuration. |
4. | Ionization enthalpy of oxygen is higher than that of nitrogen. |
For the second-period elements, the correct increasing order of first ionisation enthalpy is:
1. | Li < Be < B < C < O < N < F < Ne |
2. | Li < Be < B < C < N < O < F < Ne |
3. | Li < B < Be < C < O < N < F < Ne |
4. | Li < B < Be < C < N < O < F < Ne |
Amongst the following electronic configurations, the highest ionization energy
is represented by:
1. [Ne]3s23p3
2. [Ne]3s23p2
3. [Ar]3d104s24p3
4. [Ne]3s23p1
The first ionisation enthalpies of Na, Mg, Al, and Si are in the order of:
1. Na < Al < Mg < Si
2. Na > Mg > Al > Si
3. Na < Mg < Al < Si
4. Na > Mg > Al < Si
Element that has the greatest tendency to lose an electron is :
1. | F | 2. | Fr |
3. | S | 4. | Be |