Bright, small sizes and hydro-dispersive NIR persistent luminescence nanoparticles modified with Si and amino groups for enhanced bioimaging.

Near-infrared (NIR) persistent luminescence nanoparticles (PLNPs) with high brightness, small sizes, good hydro-dispersivity, and intrinsic surface-functional groups are desirable in biological applications. In this work, Cr-doped zinc gallogermanates ZnGaGeO:Cr (ZGGC) PLNPs were hydrothermally synthesized via 3-aminopropyltriethoxysilane (APTES) as an additive, or APTES and cetyltrimethylammonium bromide (CTAB) as two co-additives. Addition of APTES not only dramatically enhances the 696 nm NIR luminescence intensity, but also obviously decreases the particle size and introduces amino groups. In particular, the= 0.1 series ZGGC (ZGGC) with the addition of n moles equivalent APTES (ZGGC-nA) had smaller particle sizes than the= 0.2 counterpart (ZGGC-nA). The NIR afterglow intensities increased with the APTES introduction. The ZGGC-2.5A sample (also named as ZGGC, Si, -NH) exhibited maximum luminescence intensities both in solid and aqueous states. With APTES, Si atom is doped and -NHgroups are modified, the trap depth and density become larger, and the afterglow intensities and decay time are significantly enhanced. More notably, co-addition of CTAB (ZGGC-2.5A-C) (also named as ZGGC, Si, -NH') further enhances hydro-dispersivity and luminescence intensity, decreases particle sizes, and results in more prominent amino groups. The trap density is drastically higher than that without CTAB (i.e. ZGGC-2.5A). Change of Crmicroenvironment in the crystal and more defects introduction contribute to the enhanced brightness. As expected, the ZGGC,Si,-NH' PLNPs possess excellent biocompatibility, deep tissue penetration and distinguished bioimaging properties, and rechargeability with orange LED light. The ZGGC,Si,-NH' PLNPs should provide to be an excellent nanomaterial for various functionalization and bioimaging applications.