Preparation method of transition metal borides

What is claimed is: 1. A preparation method of transition metal borides comprising: mixing boron powder and metal oxide powder with a preset molar ratio to obtain a block mixture; placing the block mixture and a tungsten rod in a plasma device, wherein the block mixture is used as anode and the tungsten rod is used as cathode; and vacuumizing the plasma device, and filling a buffer gas into the plasma device, controlling the plasma device to start an arc to ignite the block mixture, controlling the plasma device to close the arc when the block mixture has been ignited, and the block mixture continues to burn and react to obtain transition metal borides when the arc is closed, wherein the metal oxide is nickel oxide; the preset molar ratio is 6:1; a space between the block mixture and the tungsten rod in the plasma device is 1 mm; a discharge current of the arc is 12 A and a discharge time is 1 s; a vacuum degree of the plasma device after the vacuumizing is less than or equal to 3 Pa; the buffer gas is argon gas; and the argon gas pressure is 70 kPa. 2. A preparation method of transition metal borides comprising: mixing boron powder and metal oxide powder with a preset molar ratio to obtain a block mixture; placing the block mixture and a tungsten rod in a plasma device, wherein the block mixture is used as anode and the tungsten rod is used as cathode; and vacuumizing the plasma device, and filling a buffer gas into the plasma device, controlling the plasma device to start an arc to ignite the block mixture, controlling the plasma device to close the arc when the block mixture has been ignited, and the block mixture continues to burn and react to obtain transition metal borides when the arc is closed, wherein the metal oxide is vanadium dioxide; the preset molar ratio is 8:1; a space between the block mixture and the tungsten rod in the plasma device is 2 mm; a discharge current of the arc is 20 A and a discharge time is 10 s; a vacuum degree of the plasma device after the vacuumizing is less than or equal to 2 Pa; the buffer gas is argon gas; and the argon gas pressure is 80 kPa. 3. The method of claim 1 , A preparation method of transition metal borides comprising: mixing boron powder and metal oxide powder with a preset molar ratio to obtain a block mixture; placing the block mixture and a tungsten rod in a plasma device, wherein the block mixture is used as anode and the tungsten rod is used as cathode; and vacuumizing the plasma device, and filling a buffer gas into the plasma device, controlling the plasma device to start an arc to ignite the block mixture, controlling the plasma device to close the arc when the block mixture has been ignited, and the block mixture continues to burn and react to obtain transition metal borides when the arc is closed, wherein the metal oxide is cobalt tetroxide; the preset molar ratio is 10:1; a space between the block mixture and the tungsten rod in the plasma device is 3 mm; a discharge current of the arc is 12 A and a discharge time is 30 s; a vacuum degree of the plasma device after the vacuumizing is less than or equal to 3 Pa; the buffer gas is argon gas, and the argon gas pressure is 70 kPa. 4. The method of claim 1 , A preparation method of transition metal borides comprising: mixing boron powder and metal oxide powder with a preset molar ratio to obtain a block mixture; placing the block mixture and a tungsten rod in a plasma device, wherein the block mixture is used as anode and the tungsten rod is used as cathode; and vacuumizing the plasma device, and filling a buffer gas into the plasma device, controlling the plasma device to start an arc to ignite the block mixture, controlling the plasma device to close the arc when the block mixture has been ignited, and the block mixture continues to burn and react to obtain transition metal borides when the arc is closed, wherein the metal oxide is ferric tetroxide; the preset molar ratio is 10:1; a space between the block mixture and the tungsten rod in the plasma device is 1 mm; a discharge current of the arc is 12 A and a discharge time is 5 s; a vacuum degree of the plasma device after the vacuumizing is less than or equal to 3 Pa; the buffer gas is argon gas; and the argon gas pressure is 70 kPa.