Influence of Nitrogen Vacancy Concentration on Mechanical and Electrical Properties of Rocksalt Zirconium Nitride Films

doi:10.1007/s40195-017-0636-x

Abstract

Abstract:

To study the influence of the nitrogen vacancy (V_N) on mechanical and electrical properties of zirconium nitride deeply, ZrN_x films with different V_N concentrations were synthesized on the Si (111) substrates by enhanced magnetic filtering arc ion plating. The morphologies, microstructures, residual stresses, compositions, chemical states, mechanical and electrical properties of the as-deposited films were characterized by field-emission scanning electron microscopy, X-ray diffraction, X-ray photoelectron spectrometry, Nanoindenter and Hall effect measurements. The results showed that ZrN_x films exhibited rocksalt single-phase structure within a V_N concentration ranging from 26 to 5%. The preferred orientation, thickness, grain size and residual stress of the ZrN _x films kept constant at different V_N concentrations. Both the nanohardness and elastic modulus first increased and then decreased with the decrease in V_N concentration, reaching the peaks around 16%. And the electric conductivity of the ZrN _x films showed a similar tendency with nanohardness. The underlying atomic-scale mechanisms of V_N concentration-dependent hardness and electric conductivity enhancements were discussed and attributed to the different electronic band structures, rather than conventional meso-scale factors, such as preferred orientation, grain size and residual stress.

Key words: ZrNx films, Nitrogen vacancy, Hardness, Electrical properties, Band structure

Ke-Chang Han, Guo-Qiang Lin, Chuang Dong, Kai-Ping Tai. Influence of Nitrogen Vacancy Concentration on Mechanical and Electrical Properties of Rocksalt Zirconium Nitride Films[J]. Acta Metallurgica Sinica (English Letters), 2017, 30(11): 1100-1108.

Figures/Tables 13

Fig. 1 Schematic diagram of enhanced magnetic filtering arc ion plating system

Table 1 Nitrogen flow rate of ZrN x films deposited by arc ion plating

Sample	S1	S2	S3	S4	S5	S6	S7
Nitrogen flow rate (sccm)	60	120	150	180	210	240	270
Percent of nitrogen in plasma (%)	16	30	37	43	49	55	60

Fig. 2 Surface a, c and cross section b, d SEM images of ZrN x films deposited at nitrogen flow rates of 60 sccm a, b and 270 sccm c, d

Fig. 3 XRD patterns of ZrN x films deposited at different nitrogen flow rates

Fig. 4 Lattice parameters a and grain sizes b of ZrN x films deposited at different nitrogen flow rates

Fig. 5 XPS wide scan spectra a and atomic concentration versus etching time b of ZrN x film deposited at a nitrogen flow rate of 120 sccm

Fig. 6 Atomic concentration a, nitrogen content x and V N concentration b of ZrN x films versus nitrogen flow rate

Fig. 7 High-resolution XPS Zr 3d a and N 1s b spectra of ZrN x film deposited at a nitrogen flow rate of 120 sccm

Fig. 8 Residual stress of ZrNx films versus VN concentration

Fig. 9 Hardness and elastic modulus of ZrN x films versus V N concentration

Fig. 10 Valence-electron concentration of ZrN x films versus V N concentration

Fig. 11 Conductivity of ZrN x films versus V N concentration

Fig. 12 Carrier concentration a and mobility b of ZrN x films versus V N concentration

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