nanoparticles. The presence of peak

nanoparticles. The presence of peaks [100], [101], [102], [110], [103] and [202] observed in PXRD confirm the formation of the ordered structure of NiSe [39]. The absence or less intense [100] peak at 2θ=28.5° (Fig. 2b and e) suggests the probable deficiency at Ni position (Ni1−xSe), which is well supported by reported Ni0.85Se [44]. As the size of the tungsten carbide balls decreased (NiSe_BM3 and NiSe_BM1.6), the intensity of [100] plane has reduced proportionally or became absent. Absence of lower angle peak (2θ=28.5°) represents Ni deficiency (Ni1−xSe) (Fig. 2b) and increase in FWHM of high intensity peak indicates the reduction in particle size (Fig. 2c). Similarly, the absence of [100] plane in the PXRD pattern of the samples NiSe_PN and NiSe_PP (Fig. 2d and e) also indicates the Ni deficiency (Ni1−xSe) with an expected composition of Ni0.85Se [44]. The crystallite size of NiSe_BM10, NiSe_BM5, NiSe_BM3, NiSe_BM1.6 and NiSe_PN, NiSe_PP were calculated by using Scherrer formula and are listed in Table S1. The transmission electron microscopy (TEM) measurements and selected area electron diffraction (SAED) patterns of the sample NiSe_PN confirmed the formation of uniform nanoparticles (Fig. 3a). On the other hand, the surfactant PVP favours the formation of nano rods of NiSe_PP (Fig. 3b). The corresponding SAED reveals crystalline nature in both compounds as shown in inset of Fig. 3a and b. However, as expected, the particles were aggregated in the case of samples synthesized by ball milling method (Fig. 4) [33]. The TEM image of NiSe (Fig. 4) samples milled for 15 min by varying tungsten carbide ball dimension from 10 to 1.6 mm shows the particles are irregular in shape and strongly agglomerated. The average crystallite size calculated from the PXRD patterns using the Scherrer formula is 9 nm
(Table S1). In addition, the SAED pattern (inset in Fig. 4) the NiSe_BM are polycrystalline in nature. Previous results suggest that PVP serves as capping agent and stabilizes the formed nanoparticles against agglomeration, but also plays a role in the formation of specific morphology such as cubes, rods or wires [45]. Infrared (IR) and Xray photoelectron spectroscopy (XPS) studies were used to explain the growth mechanism, wherein observed that both the oxygen and nitrogen atoms of the pyrrolidone unit can promote the adsorption of PVP chains on the surface of silver [46]. When PVP was introduced, it is believed that the selective interaction between PVP and various crystallographic planes of hcp could greatly reduce the growth rate along the (100) direction or enhances the growth rate along (111) direction. PVP has a polyvinyl skeleton with polar group (N-C˭O) indicating the presence of a strong interaction between the surfaces of NiSe nanoparticles and PVP through coordination bonding with the O and N atoms of the pyrrolidone ring [47]. This group can efficiently bind with the active sites of Ni, resulting in the shortage of active sites for the reduction. It is well supported that isotropic growth in the case of NiSe_PP leads to cube shaped morphology [45,48]. On the other hand the absence of surfactant (NiSe-PN) allows the growth of nanoparticle on the seed happens along all the planes with equal probability.
3.2. Reduction of PNA and PNP
The reduction of nitro aromatic compounds to the corresponding amines is considered as the important process in controlling environmental pollution [49,50]. The conventional method of reducing these