During the change of `O_(2)` to `O_(2)^(-)`, the incoming electron goes to the orbital,

During change of O_(2) to O_(2)^(2-) ion, the electrons add on which of the following orbitals ?

During change of O_(2) to O_(2)^(2-) ion, the electrons add on which of the following orbitals ?

Splitting of water molecules during light reaction of photosynthesis is associated with (a) PS I resulting the release of O_(2) , protons and transfer of electrons to PS II (b) PS II resulting in release of O_(2) , protons and transfer of electrons to PS I (c) PS II resulting in release of O_(2) , protons and transfer of electrons to PS II (d) PS I resulting in the release of O_(2) , protons and transfer of electrons to PS I. Of the above statements

Assertion O_(2) and N_(2)^(2-) have same number of electrons and same molecular orbital configuration Reasoning O_(2) and N_(2)^(2-) have the same bond order .

The anion O^(2-) is iso-electronic with

In the MO diagram for O_(2)^(Theta) ion the highest occupied orbital is .

Assume that during the electrolysis of AgNO_(3) , only H_(2)O is electrolyzed and O_(2) is formed as 2H_(2)O rarr 4H^(o+)+O_(2)+4e^(-) O_(2) formed at NTP due to passage of 2 amperes of current for 965 second is

During aerobic respiration, the passing on of the electrons removed as a part of the hydrogen atom to molecular O_2 occurs in the……..

Assume that during electrolysis of AgNO_(3) only H_(2)O is electrolyesd and O_(2) is formed at the anode as : 2H_(2)Orarr 4H^(+)+O_(2)+4e^(-) O_(2) formed at NTP due to passage of 2 amperes of current for 965 sec is :

The number of antibonding electron pairs in O_(2)^(2-) molecular ion on the basic of molecular orbital theory is