Strategies for photoluminescence enhancement of AgInS2 quantum dots and their application as bioimaging probes

“…The QY kept increase as the shell growth of ZnS in 15 min and reached maximum of 72%, but then dropped dramatically to 62% when the reaction time continued. Although the improvement of the QY was not as significant as many previous reports [8], the highest QY herein was up to ca.72%, which was considerable good as compared to those of the previously reported. It has been attributed that the surface of the QDs was well modified and it had a small amount of the non-radiative recombination at the surface sites.…”

Synthesis and temporal evolution of Zn-doped AgInS2 quantum dots

“…The QY kept increase as the shell growth of ZnS in 15 min and reached maximum of 72%, but then dropped dramatically to 62% when the reaction time continued. Although the improvement of the QY was not as significant as many previous reports [8], the highest QY herein was up to ca.72%, which was considerable good as compared to those of the previously reported. It has been attributed that the surface of the QDs was well modified and it had a small amount of the non-radiative recombination at the surface sites.…”

Synthesis and temporal evolution of Zn-doped AgInS2 quantum dots

“…Such compounds combine a series of very attractive features, including relatively low toxicity and ability to preserve chalcopyrite structure in a broad range of NP sizes and non-stoichiometries [1,19,20,24,25]. So, by varying the chalcopyrite NP size, Cu(Ag):In:S ratio [1,20,21,[23][24][25][26][27] and introducing metal dopants (for example zinc(II) [1,20,23,27]) the position of PL maximum can be varied in a very broad range -from around 500 nm to the near IR range [1,[19][20][21]26]. The attractive luminescent properties stimulated greatly both studies of the feasibility of using ternary and quaternary metal chalcogenide NPs as luminescent bio-markers [1, 9-11, 13-15, 19-24, 26-30] and, at the same time, a search of the protocols allowing direct production and stabilization of luminescent ternary Cu-In-S [25,26,28,31,32] and Ag-In-S NPs [27,30] or quaternary Zn-Cu-In-S [25] and Zn-Ag-In-Se NPs [29] in aqueous solutions.…”

“…In particular, big expectations are associated with ternary indium-based chalcopyrites [1,19,20], such as CuInS 2 and CuInS 2 /ZnS NPs [13][14][15][16]20], non-stoichiometric Cu-In-S [20,21] and Ag-In-S NPs [10], CuInS x Se 2-x NPs [22], AgInS 2 and AgInS 2 /ZnS NPs [9,11,23,24] that can also be produced by the well-known "hot injection" methods with the PL QY reaching 40-65% [1,14,21,22]. Such compounds combine a series of very attractive features, including relatively low toxicity and ability to preserve chalcopyrite structure in a broad range of NP sizes and non-stoichiometries [1,19,20,24,25].…”

Brightly luminescent colloidal Ag–In–S nanoparticles stabilized in aqueous solutions by branched polyethyleneimine

“…With a band gap of ~1.8 eV at room temperature, the AgInS 2 QDs can emit in the near-infrared region with high extinction coefficients, which offers an intriguing alternative for biological imaging applications 25 . So far, a variety of strategies have been established for the synthesis of AgInS 2 QDs [26][27][28][29] , most of which were carried out in organic phase and organic ligands were used as the capping agents for the QDs.…”

A new strategy for synthesizing AgInS2 quantum dots emitting brightly in near-infrared window for in vivo imaging