20062
If hydrogen electrode dipped in \(2\) solution of \(pH = 3\) and \(pH = 6\) and salt bridge is connected the e.m.f. of resulting cell is ............ \(\mathrm{V}\)
20063
The tendency of an electrode to lose electrons is known as
1 Electrode potential
2 Reduction potential
3 Oxidation potential
4 e.m.f.
Explanation:
(c) The magnitude of the electrode potential of a metal is a measure of its relative tendency to lose or gain electrons. i.e., it is a measure of the relative tendency to undergo oxidation (loss of electrons) or reduction (gain of electrons). \(M \to {M^{n + }} + n{e^ - }\) (oxidation potential) \({M^{n + }} + n{e^ - } \to M\) (reduction potential)
ELECTROCHEMISTRY
20064
When electric current is supplied through an ionic hydride of fused state, then
1 Hydrogen is obtained at anode
2 Hydrogen is obtained at cathode
3 No change
4 Hydride ion moves towards cathode
Explanation:
On electrolysis of fused ionic hydride \((LiH)\), hydrogen obtained at anode. \(MH + {H_2}O \to MOH + {H_2} \uparrow\)
ELECTROCHEMISTRY
20065
The hydrogen electrode is dipped in a solution of \(pH = 3\) at \({25\,^o}C\). The potential of the cell would be ............. \(\mathrm{V}\) (the value of \(2.303\,RT/F\) is \(0.059\,V\))
20062
If hydrogen electrode dipped in \(2\) solution of \(pH = 3\) and \(pH = 6\) and salt bridge is connected the e.m.f. of resulting cell is ............ \(\mathrm{V}\)
20063
The tendency of an electrode to lose electrons is known as
1 Electrode potential
2 Reduction potential
3 Oxidation potential
4 e.m.f.
Explanation:
(c) The magnitude of the electrode potential of a metal is a measure of its relative tendency to lose or gain electrons. i.e., it is a measure of the relative tendency to undergo oxidation (loss of electrons) or reduction (gain of electrons). \(M \to {M^{n + }} + n{e^ - }\) (oxidation potential) \({M^{n + }} + n{e^ - } \to M\) (reduction potential)
ELECTROCHEMISTRY
20064
When electric current is supplied through an ionic hydride of fused state, then
1 Hydrogen is obtained at anode
2 Hydrogen is obtained at cathode
3 No change
4 Hydride ion moves towards cathode
Explanation:
On electrolysis of fused ionic hydride \((LiH)\), hydrogen obtained at anode. \(MH + {H_2}O \to MOH + {H_2} \uparrow\)
ELECTROCHEMISTRY
20065
The hydrogen electrode is dipped in a solution of \(pH = 3\) at \({25\,^o}C\). The potential of the cell would be ............. \(\mathrm{V}\) (the value of \(2.303\,RT/F\) is \(0.059\,V\))
NEET Test Series from KOTA - 10 Papers In MS WORD
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ELECTROCHEMISTRY
20062
If hydrogen electrode dipped in \(2\) solution of \(pH = 3\) and \(pH = 6\) and salt bridge is connected the e.m.f. of resulting cell is ............ \(\mathrm{V}\)
20063
The tendency of an electrode to lose electrons is known as
1 Electrode potential
2 Reduction potential
3 Oxidation potential
4 e.m.f.
Explanation:
(c) The magnitude of the electrode potential of a metal is a measure of its relative tendency to lose or gain electrons. i.e., it is a measure of the relative tendency to undergo oxidation (loss of electrons) or reduction (gain of electrons). \(M \to {M^{n + }} + n{e^ - }\) (oxidation potential) \({M^{n + }} + n{e^ - } \to M\) (reduction potential)
ELECTROCHEMISTRY
20064
When electric current is supplied through an ionic hydride of fused state, then
1 Hydrogen is obtained at anode
2 Hydrogen is obtained at cathode
3 No change
4 Hydride ion moves towards cathode
Explanation:
On electrolysis of fused ionic hydride \((LiH)\), hydrogen obtained at anode. \(MH + {H_2}O \to MOH + {H_2} \uparrow\)
ELECTROCHEMISTRY
20065
The hydrogen electrode is dipped in a solution of \(pH = 3\) at \({25\,^o}C\). The potential of the cell would be ............. \(\mathrm{V}\) (the value of \(2.303\,RT/F\) is \(0.059\,V\))
20062
If hydrogen electrode dipped in \(2\) solution of \(pH = 3\) and \(pH = 6\) and salt bridge is connected the e.m.f. of resulting cell is ............ \(\mathrm{V}\)
20063
The tendency of an electrode to lose electrons is known as
1 Electrode potential
2 Reduction potential
3 Oxidation potential
4 e.m.f.
Explanation:
(c) The magnitude of the electrode potential of a metal is a measure of its relative tendency to lose or gain electrons. i.e., it is a measure of the relative tendency to undergo oxidation (loss of electrons) or reduction (gain of electrons). \(M \to {M^{n + }} + n{e^ - }\) (oxidation potential) \({M^{n + }} + n{e^ - } \to M\) (reduction potential)
ELECTROCHEMISTRY
20064
When electric current is supplied through an ionic hydride of fused state, then
1 Hydrogen is obtained at anode
2 Hydrogen is obtained at cathode
3 No change
4 Hydride ion moves towards cathode
Explanation:
On electrolysis of fused ionic hydride \((LiH)\), hydrogen obtained at anode. \(MH + {H_2}O \to MOH + {H_2} \uparrow\)
ELECTROCHEMISTRY
20065
The hydrogen electrode is dipped in a solution of \(pH = 3\) at \({25\,^o}C\). The potential of the cell would be ............. \(\mathrm{V}\) (the value of \(2.303\,RT/F\) is \(0.059\,V\))