Consider the following sets of quantum numbers:
n l m s
(i) 3 0 0 +1/2
(ii) 2 2 1 +1/2
(iii) 4 3 -2 -1/2
(iv) 1 0 -1 -1/2
(v) 3 2 3 +1/2
Which of the following sets of quantum numbers is not possible?
1. ii, iii and iv
2. i, ii, iii and iv
3. ii, iv and v
4. i and iii
Which one of the following ions is the most stable in aqueous solution?
(1) Cr3+
(2) V3+
(3) Ti3+
(4) Mn3+
(At no. Ti=22, V=23, Cr=24, Mn=25)
Given the following data:
(a) | Mass of electron: 9.11 x 10-31 kg |
(b) | Planck's constant: 6.626 x 10-34 Js |
In light of the data given above, the uncertainty involved in the measurement of velocity within a distance of 0.1 will be:
1. 5.79 x 106 ms-1
2. 5.79 x 107 ms-1
3. 5.79 x 108 ms-1
4. 5.79 x 105 ms-1
The orientation of an atomic orbital is governed by:
(1) azimuthal quantum number
(2) spin quantum number
(3) magnetic quantum number
(4) principal quantum number
An electronic configuration representing an atom in the excited state is:
How does the energy gap between successive energy levels in an atom vary from low to high n values?
(1) All energy gaps are the same
(2) The energy gap decreases as n increases
(3) The energy gap increases as n increases
(4) The energy gap changes unpredictably as n increases
The measurement of the electron position is associated with an uncertainty in momentum which is equal to 1x10-18 g cm s-1. The uncertainty in velocity of the electron will be:
(mass of an electron is 9 x 10-28 g)
1. 1 x 109 cm s-1
2. 1 x 106 cm s-1
3. 1 x 105 cm s-1
4. 1 x 1011 cm s-1
If uncertainty in position and momentum are both equal, then uncertainty in velocity will be:
1.
2.
3.
4.
Which of the following is not permissible arrangement of electrons in an atom?
1. n = 4, l = 0, m = 0, s = –1/2
2. n = 5, l = 3, m = 0, s = +1/2
3. n = 3, l = 2, m = –3, s = –1/2
4. n = 3, l = 2, m = –2, s = –1/2