(a). Of the lanthanides, cerium `(Z=58)` forms a tetrapositive ion, `Ce^(4+)` in aqueous solution. Why?
(b), The `+3` oxidation states of lanthanum `(Z=57)`, gadolinium `(Z=64)` and lutetium `(Z=71)` are especially stable. Why?
(c). Why Zr and or Nb anbd Ta exhibit similar properties ?
(d). Which oiut of the two `La(OH)_3` and `Lu(OH)_3`, is more basic and why?

Which out of the two , La(OH)_(3) and Lu(OH)_(3) , is more basic and why?

Answer the following : (a) Why inert gases are monoatomic ? (b) Potassium (K) is strongly metallic, while Cl is strongly non-metallic. Explain. ( c) Why metals are good conductors of electricity ? (d) Comment on 'Iodine possesses some metallic lusture'. (e) Of all noble metals, gold (Au) has a relatively high EA . Explain. (f) In alkali metal which element is the strongest reducing agent in aqueous solution and why? (g) Cl and be converted to Cl^(ɵ) ion easily than F to F^(ɵ) ion. Explain. (h) Why Al(OH)_(3) is amphoteric in nature ? (i) Why Be and Mg do not impart flame colouration? (j) The IE of K is same as EA of K^(o+) ion. Explain. (k) Explain the large atomic radii of noble gases.

Explain the following: a. The formation of Cs_(2)O from its element is less exothermic than the formation of ZnO from its element. b. On the basis of appropriate Born-Haber cycle, state what factor (s) is (are)responsible for the fact that lithium nitride (Li_(3)N) is more stable while potassium nitride (K_(3)N) is unstable. c. Why Al^(3+) is the only stable oxidation state of Al in its compounds while TI has +1 and +3 oxidation states? d. Pb^(4+) is a powerful oxidising agent. What is the reducing ability of Pb^(2+) e. Which is more soluble in water LiI or KI ?

(a) Out of Cu^+ and V^(2+) which will be coloured and why? (Atomic number of V is 23 and Cu is 29). (b) Why is + 3 oxidation state of Fe (Z = 26) more stable than its + 2 oxidation state? ( c) Is Au (Z = 79) a transition metal or not? Explain.

Read the passage given below and answer the following questions: Within the 3d series, manganese exhibits oxidation states in aqueous solution from +2 to +7, ranging from Mn^(2+)(aq) to MnO_(4)^(-) (aq). Likewise, iron forms both Fe^(2+)(aq) and Fe^(3+)(aq) as well as the FeO_(4)^(2-) ion. Cr and Mn form oxyions CrO_(4)^(2-) , MnO_(4)^(-) , owing to their willingness to form multiple bonds . The pattern with the early transition metals-in the 3d series up to Mn, and for the 4d, 5d metals up to Ru and Os—is that the maximum oxidation state corresponds to the number of ‘‘outer shell’’ electrons. The highest oxidation states of the 3d metals may depend upon complex formation (e.g., the stabilization of Co^(3+) by ammonia) or upon the pH (thus MnO_(4)^(2-) (aq) is prone to disproportionation in acidic solution). Within the 3d series, there is considerable variation in relative stability of oxidation states, sometimes on moving from one metal to a neighbor, thus, for iron, Fe^(3+) is more stable than Fe^(2+) , especially in alkaline conditions, while the reverse is true for cobalt. The ability of transition metals to exhibit a wide range of oxidation states is marked with metals such as vanadium, where the standard potentials can be rather small, making a switch between states relatively easy. (Cotton, S. A. (2011). Lanthanides: Comparison to 3d metals. Encyclopedia of inorganic and Bioinorganic Chemistry.) In the following questions, a statement of assertion followed by a statement of reason is given. Choose the correct answer out of the following choices on the basis of the above passage. Assertion: Fe^(3+) is more stable than Fe^(2+) Reason: Fe^(3+) has 3d^(5) configuration while Fe^(2+) has 3d^(6) configuration.

Read the passage given below and answer the following questions: Within the 3d series, manganese exhibits oxidation states in aqueous solution from +2 to +7, ranging from Mn^(2+)(aq) to MnO_(4)^(-) (aq). Likewise, iron forms both Fe^(2+)(aq) and Fe^(3+)(aq) as well as the FeO_(4)^(2-) ion. Cr and Mn form oxyions CrO_(4)^(2-) , MnO_(4)^(-) , owing to their willingness to form multiple bonds . The pattern with the early transition metals-in the 3d series up to Mn, and for the 4d, 5d metals up to Ru and Os—is that the maximum oxidation state corresponds to the number of ‘‘outer shell’’ electrons. The highest oxidation states of the 3d metals may depend upon complex formation (e.g., the stabilization of Co^(3+) by ammonia) or upon the pH (thus MnO_(4)^(2-) (aq) is prone to disproportionation in acidic solution). Within the 3d series, there is considerable variation in relative stability of oxidation states, sometimes on moving from one metal to a neighbor, thus, for iron, Fe^(3+) is more stable than Fe^(2+) , especially in alkaline conditions, while the reverse is true for cobalt. The ability of transition metals to exhibit a wide range of oxidation states is marked with metals such as vanadium, where the standard potentials can be rather small, making a switch between states relatively easy. (Cotton, S. A. (2011). Lanthanides: Comparison to 3d metals. Encyclopedia of inorganic and Bioinorganic Chemistry.) In the following questions, a statement of assertion followed by a statement of reason is given. Choose the correct answer out of the following choices on the basis of the above passage. Assertion: Highest oxidation state is exhibited by transition metal lying in the middle of the series. Reason: The highest oxidation state exhibited corresponds to number of (n-1)d electrons.