reports on QDLEDs have started to a

reports on QDLEDs have started to appear that ranged from device
physics or mechanism [16] to search for new materials and device
architectures or materials engineering. Apart from binary nanocrystals,
core–shell [10,17,18], doped [11,19], and alloyed nanostructures
[14] and nanorods [20] and nanofibers [21] are being
used as an active material in order to improve the quantum
efficiency, color tunability, and stability of the LEDs.
With the search for new quantum dots for various device
applications, the issue of toxic nature of elements in the quantum
dots has become more relevant since most of the high-emissive
nanocrystals contain cadmium or lead. Also, the synthesis process
of these nanocrystals involves complex steps [9,10,13,14,17,22].
Recently, some cadmium-free ternary I–III–VI quantum dots have
been grown for the use as an active layer in QDLEDs [23]. In this
direction, color tuning, ranging from the near-IR to green emissions,
has been observed in the QDLEDs using multinary ZnCuInS/
ZnSe/ZnS or CuInSe2/ZnS nanoparticles, where ZnSe and ZnS acted
as a shell layer to protect the nanostructures from degradation due
to an exposure to the atmosphere [24,25]. The wavelength of
the electroluminescence (EL) emission of the QDLEDs based on
these nanoparticles could be tuned by varying the diameter of the
quantum dots. Such nanoparticles are also synthesizable in the
gram scale.
In this work, we have chosen another type of multinary nanoparticles,
namely, zinc-alloyed silver–indium-sulfide (AIZS), which
do not contain any toxic elements, for the fabrication of QDLEDs.
Here, tuning of PL emission of the nanocrystals could be achieved by
the ratio of the initial cationic precursors [26,27]. That is, the molar
ratio of silver and zinc precursors tunes the optical absorption and
the PL emission of AIZS nanoparticles while retaining the diameter
of the quantum dots the same. Here, the bandgap of the nanocrystals
widens with an increase in the zinc content in the quantum
structures. In addition, by doping the nanostructures with transition
metal ions (manganese), an intense and stable emission from the dstates
of the dopants could be achieved [28–30]. Due to a high
extinction coefficient, these nanomaterials moreover absorbs the
PL emission of the host matrices or organic hole-transport materials
making the EL spectrum narrower, unique, and characteristic to only
the quantum structures [13,19]. These materials are also being used
for bio-imaging and solid-state lighting, as well as solar harvesters
for solution-processed solar-cells [31]. In this work, we report
fabrication and characterization of QDLEDs based on nontoxic AIZS
nanoparticles and manganese-doped AIZS nanoparticles as the
active layer.