This paper is different from previo

This paper is different from previous reports involving the usage of H2O2 for the synthesis of silver nanoplates as they utilized only the oxidizing capability of H2O2 for the selective etching of silver nanostructures [36,40,41,52]. Additional silver ions, strong reducing agent, and trisodium citrate were not necessary for thesynthesis of AgNPls utilizing our approach. We employed just asufficient amount of NaBH4 for silver nanosphere preparation onlyto ensure the complete reduction of Agþ to Ag0 without leaving theresidual amount of unreacted reducing agent. Moreover, H2O2 werethe principal shape-controlling reagent in our study, not themixture of H2O2 and NaBH4 as previously reported [41]. H2O2 wassubsequently added into a colloid of AgNSs to trigger the shapetransformation process in order to deliberately separate thenucleation of silver seeds and growth of the silver nanoplates. Inaddition, the amount of H2O2 required for the shape transformationwas minimized as the H2O2-oxidation was not competing with theNaBH4-reduction. Our approach can selectively fabricate silvernanoplate with various color e.g. red, pink, and violet. The ability toselectively control the LSPR property of silver nanoplates extendsthe range of applications and broadens the exploration of thisfunctional materials in the fields of colorimetric sensor especiallythose in medical applications [54] and chemical sensors [55].

This paper is different from previous reports involving the usage of H2O2 for the synthesis of silver nanoplates as they utilized only the oxidizing capability of H2O2 for the selective etching of silver nanostructures [36,40,41,52]. Additional Silver ions, strong reducing Agent, Trisodium citrate and were not necessary for the
synthesis of AgNPls utilizing our approach. We just employed a
sufficient amount of NaBH4 Preparation for Silver Nanosphere only
to ensure the reduction of Complete Agþ to Ag0 without Leaving the
residual amount of unreacted reducing Agent. Moreover, H2O2 were
the Principal shape-controlling reagent in our Study, not the
mixture of H2O2 and NaBH4 As previously reported [41]. H2O2 was
added subsequently into a colloid of AgNSs to Trigger the shape
Transformation Process in Order to deliberately Separate the
nucleation and growth of the Seeds of Silver Silver Nanoplates. In
addition, the amount of H2O2 required shape for the Transformation
was minimized As the H2O2-oxidation was not competing with the
NaBH4-reduction. Can Selectively our approach fabricate Silver
Nanoplate eg with Various Color Red, Pink, and violet. The ability to
Selectively Control of the LSPR Property Nanoplates Silver extends
the Range of Applications and broadens the Exploration of this
functional Materials in the Fields of colorimetric sensor especially
those in Medical Applications [54] and Chemical sensors [55].

This paper is different from previous reports involving the usage of H2O2 for the synthesis of silver nanoplates as they. Utilized only the oxidizing capability of H2O2 for the selective etching of silver nanostructures [36 40,,, 41 52]. Additional. Silver ions strong agent and, reducing, trisodium citrate were not necessary for the
synthesis of AgNPls utilizing our, approach. We employed just a
.Sufficient amount of NaBH4 for silver nanosphere preparation only
to ensure the complete reduction of Ag þ to Ag0 without. Leaving the
residual amount of unreacted reducing agent. Moreover H2O2, were
the principal shape-controlling reagent in. Our, study not the
mixture of H2O2 and NaBH4 as previously reported [41]. H2O2 was
subsequently added into a colloid of. AgNSs to trigger the shape
.Transformation process in order to deliberately separate the
nucleation of silver seeds and growth of the silver, nanoplates. In
addition the amount, of H2O2 required for the shape transformation
was minimized as the H2O2-oxidation was not competing. With the
NaBH4-reduction. Our approach can selectively fabricate silver
nanoplate with various color e.g. Red pink and,,, Violet. The ability to
.Selectively control the LSPR property of silver nanoplates extends
the range of applications and broadens the exploration. Of this
functional materials in the fields of colorimetric sensor especially
those in medical applications [] and 54 chemical. 55 sensors [].