PREPARATION METHOD OF SUB-MICRON POWDER OF HIGH-ENTROPY NITRIDE VIA NITRIDE THERMAL REDUCTION WITH SOFT MECHANO-CHEMICAL ASSISTANCE

Abstract

A preparation method of submicron powder of high-entropy nitride via nitride thermal reduction with mechano-chemical assistance, comprising material preparationgrindingactivationpreformingreaction. In the present invention, high-entropy metal nitride and silicon nitride is used as raw materials, soft mechanochemical activation technologies are used to reduce reaction activation energy of the system, thereafter, by thermal reduction of the nitride, high-purity high-entropy nitride powder is prepared with solid phase methods, and the shortage of high-purity high-entropy nitride powder is addressed. There is no impure phase in the (Hf.sub.0.2Zr.sub.0.2Ti.sub.0.2Nb.sub.0.2Ta.sub.0.2)N high entropy powder prepared according to the present invention, and a single phase solid solution of good crystallinity is formed, and distribution of elements and ingredients in the powder is even, no foreign element is present, and oxygen content is controlled to be less than 0.3%.

Claims

1. A preparation method of sub-micron powder of high-entropy nitride via nitride thermal reduction with soft mechano-chemical assistance, wherein the method comprising: (1) material preparation: mixing ingredients at a molar ratio of HfO.sub.2, ZrO.sub.2, TiO.sub.2, Nb.sub.2O.sub.5, Ta.sub.2O.sub.5, Si.sub.3N.sub.4=2:2:2:1:1:6 and obtaining a mixed material; (2) grinding: weighing the mixed material, placing the mixed material in a mixing mill, adding deionized water, until a solid content is 45%?75%, adding zirconia balls with a particle size of 1?3 mm, grinding until the mixed material is dispersed evenly; (3) activation: placing the mixed material after grinding into a mixing dispenser, conducting soft mechano-chemical activation at a rate of 800?1600 r/min, activation time is 5?20 h, separating the zirconia balls and drying the mixed material; (4) prefabrication: compacting powder of the mixed material after drying to be loose pieces of 5?20 g with circular cast steel molds, wherein prefabrication pressure is 10?50 MPa, and pressure is maintained for 10?50 s; and (5) reaction: putting the prefabricated loose pieces into a vacuum synthesis furnace, vacuuming the vacuum synthesis furnace, filling N.sub.2 shielding air, heating the vacuum synthesis furnace until 1500?2000? C. for synthesis reaction, maintaining reaction temperature for 30?90 min, furnace cooling and obtaining the (Hf.sub.0.2Ti.sub.0.2Zr.sub.0.2Nb.sub.0.2Ta.sub.0.2)N high-entropy powder.

2. The preparation method of sub-micron powder of high-entropy nitride via nitride thermal reduction with soft mechano-chemical assistance according to claim 1, wherein in step (1), the molar ratio of the ingredients is HfO.sub.2:ZrO.sub.2, TiO.sub.2, Nb.sub.2O.sub.5, Ta.sub.2O.sub.5, Si.sub.3N.sub.4=2:2:2:1:1:10.

3. The preparation method of sub-micron powder of high-entropy nitride via nitride thermal reduction with soft mechano-chemical assistance according to claim 1, wherein in step (2), the solid content is 60% and a ball material ratio is 3:1.

4. The preparation method of sub-micron powder of high-entropy nitride via nitride thermal reduction with soft mechano-chemical assistance according to claim 1, wherein in step (3), a rotation speed of the mixing dispenser is 1500 r/min.

5. The preparation method of sub-micron powder of high-entropy nitride via nitride thermal reduction with soft mechano-chemical assistance according to claim 1, wherein in step (5), synthesis temperature is 1600? C.

6. The preparation method of sub-micron powder of high-entropy nitride via nitride thermal reduction with soft mechano-chemical assistance according to claim 1, wherein a heating ratio of the vacuum synthesis furnace is 10?30? C./min.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0020] FIG. 1 is an XRD diagram showing (Hf.sub.0.2Zr.sub.0.2Ti.sub.0.2Nb.sub.0.2Ta.sub.0.2)N high-entropy powder;

[0021] FIG. 2 shows SEM particle size analysis and energy dispersive spectroscopy analysis;

[0022] FIG. 3 shows transmission electron diffraction (TED) and energy dispersive spectroscopy analysis.

EMBODIMENTS

[0023] To make the technical solutions of the present invention easy to understand, hereinafter, a clear and complete description will be given to the technical solutions of the present invention by combination of the drawings and the embodiments.

Embodiment 1

[0024] A preparation method of sub-micron powder of high-entropy nitride via nitride thermal reduction with soft mechano-chemical assistance in the present embodiment comprising the following steps: [0025] (1) Material preparation: mixing ingredients at a molar ratio of HfO.sub.2, ZrO.sub.2, TiO.sub.2, Nb.sub.2O.sub.5, Ta.sub.2O.sub.5, Si.sub.3N.sub.4=2:2:2:1:1:6 and obtaining a mixed material; [0026] (2) Grinding: weighing the mixed material, placing the mixed material in a mixing mill, adding deionized water until a solid content is 45%, adding zirconia balls with a particle size of 1?3 mm as per a ball material ratio of 3:1, grinding to have the mixed material evenly dispersed; [0027] (3) Activation: adding the mixed material after grinding into a mixing disperser, conducting soft mechano-chemical activation at a speed of 800 r/min, activation time is 5 h, separating the zirconia balls and drying the mixed material; [0028] (4) Prefabrication: compacting powder of the mixed material after drying to be loose pieces of 5 g with circular cast steel molds with a diameter of 1 mm, preforming pressure is 10 MPa, and pressure is maintained for 50 s; [0029] (5) Reaction: putting the preformed loose pieces into a vacuum synthesis furnace, vacuuming the vacuum synthesis furnace, filling N.sub.2 shielding air, heating the vacuum synthesis furnace at a speed of 10?30? C./min until 1500? C. for synthesis reaction, maintaining the temperature and reacting for 90 min, furnace cooling and obtaining (Hf.sub.0.2Ti.sub.0.2Zr.sub.0.2Nb.sub.0.2Ta.sub.0.2)N high entropy powder.

Embodiment 2

[0030] A preparation method of sub-micron powder of high-entropy nitride via nitride thermal reduction with soft mechano-chemical assistance in the present embodiment, comprising the following steps: [0031] (1) Material preparation: mixing ingredients as per a molar ratio of HfO.sub.2, ZrO.sub.2, TiO.sub.2, Nb.sub.2O.sub.5, Ta.sub.2O.sub.5, Si.sub.3N.sub.4=2:2:2:1:1:8 and obtaining a mixed material; [0032] (2) Grinding: weighing the mixed material, putting into a mixing mill, adding deionized water of an appropriate amount so that a solid content is 50%, adding zirconia balls with a particle size of 1?3 mm as per a ball material ratio of 3:1, grinding to have materials evenly dispersed; [0033] (3) Activation: putting the mixed material after grinding into a mixing dispenser, conducting soft mechano-chemical activation at a speed of 1000 r/min, activation time is 8 h, separating the zirconia balls and drying the mixed material; [0034] (4) Preforming: compacting powder of the mixed material to be loose pieces of 10 g by circular cast steel molds with a diameter of 1 mm, preforming pressure is 200 MPa and pressure is maintained for 40 s; [0035] (5) Reaction: putting the preformed loose pieces into a vacuum synthesis furnace, vacuuming the vacuum synthesis furnace, filling N.sub.2 shielding air, heating the vacuum synthesis furnace as per a speed of 10?30? C./min until 1700? C. for synthesis reaction, maintaining the temperature and reacting for 75 min, furnace cooling and obtaining (Hf.sub.0.2Ti.sub.0.2Zr.sub.0.2Nb.sub.0.2Ta.sub.0.2)N high entropy powder.

Embodiment 3

[0036] A preparation method of sub-micron powder of high-entropy nitride via nitride thermal reduction with soft mechano-chemical assistance in the present embodiment comprising the following steps: [0037] (1) Material preparation: mixing ingredients as per a molar ratio of HfO.sub.2, ZrO.sub.2, TiO.sub.2, Nb.sub.2O.sub.5, Ta.sub.2O.sub.5, Si.sub.3N.sub.4=2:2:2:1:1:10 and obtaining a mixed material; [0038] (2) Grinding: weighing the mixed material, putting into a mixing mill, adding deionized water until a solid content is 60%, adding zirconia balls with a particle diameter of 1?3 mm as per a ball material ratio of 3:1, grinding to have materials dispersed evenly; [0039] (3) Activation: putting the mixed material after grinding into a mixing dispenser, conducting soft mechano-chemical activation at a speed of 1200 r/min, activation time is 12 h, separating the zirconia balls and drying the mixed material; [0040] (4) Preforming: compacting powder of the mixed material after drying to be loose pieces with a mass of 15 g with circular cast steel molds with a diameter of 1 mm, preforming pressure is 30 MPa and pressure is maintained for 30 s; [0041] (5) Reaction: putting the preformed loose pieces into a vacuum synthesis furnace, vacuuming the vacuum synthesis furnace, filling N.sub.2 shielding air, heating the vacuum synthesis furnace as per a heating rate of 10?30? C./min until 1600? C. for synthesis reaction, maintaining the temperature and reacting for 60 min, furnace cooling and obtaining (Hf.sub.0.2Ti.sub.0.2Zr.sub.0.2Nb.sub.0.2Ta.sub.0.2)N high entropy powder.

Embodiment 4

[0042] A preparation method of sub-micron powder of high-entropy nitride via nitride thermal reduction with soft mechano-chemical assistance in the present embodiment comprising the following steps: [0043] (1) Material preparation: mixing ingredients as per a molar ratio of HfO.sub.2, ZrO.sub.2, TiO.sub.2, Nb.sub.2O.sub.5, Ta.sub.2O.sub.5, Si.sub.3N.sub.4=2:2:2:1:1:12 and obtaining a mixed material; [0044] (2) Grinding: weighing the mixed material, putting into a mixing mill, adding deionized water until a solid content is 70%, adding zirconia balls with a particle size of 1?3 mm as per a ball material ratio of 3:1, and grinding to have the ingredients dispersed evenly; [0045] (3) Activation: putting the mixed material after grinding into a mixing dispenser, conducting soft mechano-chemical activation at a speed of 1400 r/min, activation time 15 h, separating the zirconia balls and drying the mixed material; [0046] (4) Preforming: compacting the mixed material after drying to be loose pieces with a mass of 18 g with circular cast steel molds with a diameter of 1 mm, preforming pressure is 40 MPa and pressure is maintained for 20 s; [0047] (5) Reaction: putting the preformed loose pieces into a vacuum synthesis furnace, vacuuming the vacuum synthesis furnace, filling N.sub.2 shielding air, heating the vacuum synthesis furnace until 1800? C. at a heating rate of 10?30? C./min for synthesis reaction, maintaining the temperature and reacting for 45 min, furnace cooling and obtaining (Hf.sub.0.2Ti.sub.0.2Zr.sub.0.2Nb.sub.0.2Ta.sub.0.2)N high entropy powder.

Embodiment 5

[0048] A preparation method of sub-micron powder of high-entropy nitride via nitride thermal reduction with soft mechano-chemical assistance in the present embodiment comprising the following steps: [0049] (1) Material preparation: mixing ingredients as per a molar ratio of HfO.sub.2, ZrO.sub.2, TiO.sub.2, Nb.sub.2O.sub.5, Ta.sub.2O.sub.5, Si.sub.3N.sub.4=2:2:2:1:1:14 and obtaining a mixed material; [0050] (2) Grinding: weighing the mixed material, putting into a mixing mill, adding deionized water until a solid content is 75%, adding zirconia balls with a particle size of 1?3 mm at a ball material ratio of 3:1, grinding to have the ingredients dispersed evenly; [0051] (3) Activation: putting the mixed material after grinding into a mixing dispenser, conducting soft mechano-chemical activation at a speed of 1600 r/min, activation time is 20 h, separating the zirconia balls and drying the mixed material; [0052] (4) Preforming: compacting powder of the mixed material to be loose pieces with a mass of 20 g with circular cast steel molds with a diameter of 1 mm, preforming pressure is 50 MPa and pressure if maintained for 10 s; [0053] (5) Reaction: putting the preformed loose pieces into a vacuum synthesis furnace, vacuuming the vacuum synthesis furnace, filling N.sub.2 shielding air, heating the vacuum synthesis furnace until 2000? C. at a heating rate of 10?30? C./min for synthesis reaction, maintaining the temperature and reacting for 30 min, furnace cooling and obtaining (Hf.sub.0.2Ti.sub.0.2Zr.sub.0.2Nb.sub.0.2Ta.sub.0.2)N high entropy powder.

[0054] Characterization was given to the (Hf.sub.0.2Zr.sub.0.2Ti.sub.0.2Nb.sub.0.2Ta.sub.0.2)N high-entropy powder, FIG. 1 is an XRD diagram of the (Hf.sub.0.2Zr.sub.0.2Ti.sub.0.2Nb.sub.0.2Ta.sub.0.2)N high-entropy powder, FIG. 2 shows SEM particle size analysis and energy dispersive spectroscopy analysis and FIG. 3 shows transmission electron diffraction (TED) and energy dispersive spectroscopy analysis.

[0055] From the phase analysis in FIG. 1, it can be known that there was no impure phase in the (Hf.sub.0.2Zr.sub.0.2Ti.sub.0.2Nb.sub.0.2Ta.sub.0.2)N high-entropy powder, single-phase solid solution was formed with good crystailinity, and oxygen content was controlled to be less than 0.3%. By analyzing the XRD data it can be known that the lattice parameter was 4.5045 ?, and the average crystallite size was calculated to be 35 nm according to Scherrer Equation.

[0056] From the appearance as shown in FIG. 2, it can be known that the powder was of regular appearances, with few soft reunions. By calculating the particle size of the powder, a particle size distribution diagram FIG. 2(c) was obtained, a particle distribution range of the powder was 0.1?1 m with an average particle size of 0.49 m. By conducting elemental analysis for the powder from a macro perspective, it was known that distribution of elements and ingredients was uniform and no impure element exists.

[0057] As shown in FIG. 3, to further analyze the high entropy nitride powder, transmission electron diffraction (TED) and energy dispersive spectroscopy analysis was given to samples of the powder. Some particles in the powder had sizes about 200 nm, a large quantity of dislocations existed in irregular places in the surface, which was caused by a large number of distortion of lattice during formation of the solid solution, resulting in a large number of dislocation, dislocation overlapping resulted in irregular particle surface, and some step-like growth morphologies appeared. By analysis of electron diffraction mottles it can be known that the solid solution was of cubic phase, which matched the data and results in XRD analysis. Finally elemental analysis was given to single particles, it was found that, distribution of metallic elements in the particles was uniform, and the powder was solid solution with evenly distributed Hf, Zr, Ti, Nb and Ta metallic elements.

[0058] From the foregoing analysis, it can be concluded that, particle sizes of the single-phase (Hf.sub.0.2Zr.sub.0.2Ti.sub.0.2Nb.sub.0.2Ta.sub.0.2)N high-entropy powder prepared via thermal reduction of nitride with mechano-chemical assistance fall into the submicron level, and distribution of metallic elements is even.

[0059] It shall be understood that, the embodiments given here are only some embodiments of the present invention rather than all, the embodiments are exemplary, and intended to provide a clear and obvious way to help understanding the contents of the present invention and shall be not construed to be limitations on the present invention. Without departing from the spirit of the present invention, all other embodiments that those of ordinary skill can obtain without paying creative effort and simple replacement and all variations of the technical solutions of the present invention shall fall into the protection scope of the present invention.