. 2016 Sep 27;6:34149. doi: 10.1038/srep34149

Table 1.

Modified electrode	Method of detection	LR (μM)	LOD (μM)	Ref.
AgNPs/DNA/GCE	Amperometry	2.0–2500	0.6	62
GNs/Ag/GCE	Amperometry	100.0–40,000	28.0	63
AgNWs/CS/GCE	Amperometry	8.0–1350	2.0	64
AgNWs/PtE	Amperometry	0.5–3000	0.2	65
ZnONRs/AgNPs/GCE	Amperometry	0.9–983.0	0.9	66
SiNWs/AgNPs/GCE	Amperometry	0.2 −20,000	0.2	67
AgNPs/GCE	Amperometry	4.0–60.0	1.3	68
PVP–AgNWs/GCE	Amperometry	20.0–3620	2.3	69
GR/AgNWs/GCE	Amperometry	1	1.0	70
CNT/AgNPs/GCE	Amperometry	9.0–9000	1.6	71
RGO/AgNPs/GCE	Amperometry	100.0–8000	7.1	72
Ag/GCE	Amperometry	5.0–12,000	0.5	73
Ag-AlOOH-rGO	Amperometry	5.0 to 4200	1.8	74
Ag-Bt/GCE	Amperometry	—	9.1	75
Ag₂MoO₄/GCE	Amperometry	0.04–240	0.03	This work

Comparison of analytical performance of Ag₂MoO₄ modified electrode with previously reported similar modified electrodes for the detection of H₂O₂. Abbreviations: LR–linear response range; LOD–limit of detection; NPs–nanoparticles; NWs–nanowires; Ag- Silver nanoparticles; CS–chitosan; GCE–glassy carbon electrode; GR–graphene; PVP–polyvinylpyrolidone; GNs–graphene nanosheets; PtE–platinum electrode; CNT–carbon nanotubes; NRs–nanorods; RGO–reduced graphene oxide; AlOOH- Aluminum oxyhydroxide: Ag-Bt- silver nanoparticle-incorporated bentonite clay.