The reaction 2FeC l_3 + SnC l_2 2FeC l_2 + SnC l_4 is an example …

$U\,\,\, 1s^2 \,2s^2 \,2p^3$
$V\,\,\, 1s^2\,2s^2 \,2p^6 \,3s^1$
$W\,\,\, 1s^2\,2s^2\, 2p^6\,3s^2\,3p^2$
$X\,\,\, 1s^2\,2s^2\,2p^6\,3s^2\,3p^6\,3d^5\, 4s^2$
$Y\,\,\, 1s^2\, 2s^2\,2p^6\,3s^2\,3p^6\,3d^{10}\, 4s^2\, 4p^6$

Determine which sequence of elements satisfy the following statements :
$(i)$ Element forms a carbonate which is not decomposed by heating
$(ii)$ Element is most likely to form coloured ionic compounds
$(iii)$ Element has largest atomic radius
$(iv)$ Element forms only acidic oxide

→

For a reaction at equilibrium

$A ( g ) \rightleftharpoons B ( g )+\frac{1}{2} C ( g )$

the relation between dissociation constant ( $K$ ), degree of dissociation $(\alpha)$ and equilibrium pressure $(p)$ is given by?

→

For osazone formation, the effective structural unit necessary is

→

If a system is at equilibrium the rate of forward to the reverse reaction is

→

No. of structrual isomer of $C_4H_{11}N$

→

Given below are two statements: one is labelled as Assertion(A) and the other is labelled as Reason (R).
Assertion(A) : In p-block, when we move down in group, stability of highest oxidation state decreases.
Reason (R) : In d-block, when we move down in group, stability of highest oxidation state increases.
In the light of the above statements, choose the most appropriate answer from the options given below: