Preparation method of quasi one-dimensional boron nitride nanostructure

A nanostructure and boron nitride technology, applied in chemical instruments and methods, nitrogen compounds, inorganic chemistry, etc., can solve the problems of low output, poor crystallinity, and low purity of boron nitride tubes, and achieve easy control of process parameters, Large product output and good repeatability

Inactive Publication Date: 2009-08-12
INST OF METAL RESEARCH - CHINESE ACAD OF SCI
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

Although boron nitride nanotubes were successfully prepared for the first time in 1995, and there have been many methods to prepare boron nitride nanotubes, such as arc method, laser sputtering method, chemical vapor deposition, solid-state reaction, etc., but so far , the yield of boron nitride tubes is very low and the purity is also poor
As another important boron nitride one-dimensional nanostructure, boron nitride nanowires, there are fewer reports on successful synthesis; only a few reports also have defects such as poor crystallinity, low purity and low yield.
In conclusion, the bottleneck of difficult sample preparation has significantly restricted the study of the intrinsic properties of boron nitride one-dimensional nanostructures and the realization of their potential applications.

Method used

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Embodiment 1

[0024] The floating catalyst is ferrocene, the weight ratio relationship between the amount used and the sum of the reactants (boron powder, boron oxide) is 0.1, the evaporation temperature is 150°C, the flow rate of ammonia gas is 100 sccm, the flow rate of nitrogen gas is 300 sccm, boron powder and boron oxide The weight ratio is 1:4, the reaction temperature is 1300°C, the heating rate is 25°C / min, and the reaction time is 1 hour. Obtain a diameter of about 50 nanometers and a bamboo-shaped boron nitride nanotube with a length of tens of micrometers, see figure 1 . From the high-resolution image, it can be clearly seen that (0002) is arranged parallel to the axial direction, and its purity is 95%.

Embodiment 2

[0026] The floating catalyst is nickelocene, the weight ratio relationship between the amount used and the sum of reactants (boron powder, boron oxide) is 0.2, the evaporation temperature is 200°C, the flow rate of ammonia gas is 50 sccm, the flow rate of nitrogen gas is 150 sccm, boron powder and boron oxide The weight ratio is 1:4, the reaction temperature is 1400°C, the heating rate is 35°C / min, and the reaction time is 1 hour. A cup-stacked boron nitride nanowire with a diameter of about 100 nanometers and a length of tens of microns is obtained, see figure 2 . From the high-resolution image, it can be clearly seen that the (0002) planes are arranged perpendicular to the axial direction, and the purity is 90%.

Embodiment 3

[0028] The floating catalyst is cobaltocene, the weight ratio relationship between the amount used and the sum of the reactants (boron powder, boron oxide) is 0.2, the evaporation temperature is 300°C, the flow rate of ammonia gas is 50 sccm, the flow rate of nitrogen gas is 200 sccm, boron powder and boron oxide The weight ratio is 1:7, the reaction temperature is 1380°C, the heating rate is 40°C / min, and the reaction time is 1 hour. Obtain cup-stacked boron nitride nanowires with a diameter ranging from tens to two to three hundred nanometers and a length of tens of microns. There are many secondary growth sheets and small nanotubes on the surface, see image 3 . The arrangement of the (0002) vertical axis mentioned in Example 2 can be verified from selected area electron diffraction, and its purity is 90%.

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Abstract

The invention relates to a controllable preparation method of a quasi-one-dimensional boron nitride nanostructure. By adjusting the preparation parameters, various quasi-one-dimensional boron nitride nanotubes, stacked cup-shaped boron nitride nanowires and other quasi-one-dimensional can be prepared under control. Nano structure, large yield and high purity of the product. The specific method is: use nickelocene, ferrocene, cobaltocene or their mixture as the floating catalyst precursor, volatilize in the low temperature area and be carried by the carrier gas to the high temperature area to decompose into a metal catalyst, and promote the mixture of boron powder and boron oxide to form B2O2 vapor reacts with ammonia to form one-dimensional boron nitride nanostructures with different morphologies. Boron nitride nanowires and bamboo-shaped boron nitride nanotubes with different diameters and shapes can be obtained by controlling reaction parameters such as catalyst components, reaction time, catalyst evaporation temperature, and ammonia flow rate. The obtained boron nitride nanowires and nanotubes have essentially different structures, the former (0002) plane grows vertically to the axial direction, and the latter (0002) plane grows parallel to the axial direction.

Description

Technical field: [0001] The invention relates to a controllable preparation method of a boron nitride quasi-one-dimensional nanostructure, which is suitable for the controllable preparation of quasi-one-dimensional boron nitride nanotubes and nanowires with different shapes and structures, and the yield of the product is large and the purity is high. Background technique: [0002] Since the discovery of carbon nanotubes in 1991, the preparation and application of various systems of one-dimensional nanostructures have attracted widespread attention. The structure of hexagonal boron nitride is very close to that of graphite, which can be regarded as the replacement of carbon atoms in graphite by nitrogen atoms and boron atoms to form sp 2 Hybrid graphite-like lamellar structure. The electrical properties (bandgap width) of carbon nanotubes vary with diameter and chirality, which is difficult to control, thus increasing the difficulty of practical application. Compared with c...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): C01B21/064
Inventor 刘畅汤代明成会明
Owner INST OF METAL RESEARCH - CHINESE ACAD OF SCI
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