`._(13)Al^(27)` is a stable isotope. `._(13)Al^(29)` is expected to disintegrate by

_(1)^(1)H is a stable isotope . _(1)^(3)H is expected to disintegrated by :

(Ho)_(67)^(165) is stable isotope. (Ho)_(67)^(150) is expected to distegrate by:

If radius of the ._(13)^(27)Al nucleus is taken to be R_(AI) , then the radius of ._(53)^(125)Te nucleus is nearly

If radius of the ._(13)^(27)Al nucleus is taken to be R_(AI) , then the radius of ._(53)^(125)Te nucleus is nearly

If radius of the ._(13)^(27)Al nucleus is estimated to be 3.6 Fermi, then the radius of ._(52)^(125)Te nucleus be nerarly:

Suppose, we think of fission of a ._26Fe^(56) nucleus into two equal fragments ._13Al^(28) . Is the fission energetically possible? Argue by working out Q of the process. Given m(._26Fe^(56))=55.93494u, m(._13Al^(28))=27.98191 u.

Assertion : K_(2)[Ni(EDTA)] is more stable than K_(3)[Al(C_(2)O_(4))_(3)] . Reason : Ni is a transition element while Al is a non-transition element .

[{:(1,3),(2,7):}] find the inverse of matrix

If the radii of nuclei of ._(13)Al^(27) and ._(30)Zn^(64) are R_(1) and R_(2) respectively, then (R_(1))/(R_(2))=

Why Al^(3+) is the only stable oxidation state of Al in its compounds while Tl has +1 and +3 oxidation states?