RU2463253C1 - Method of producing material for field-emission cathode - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention can be used in electronics and nanotechnology. The method of producing material for a field-emission cathode based on carbon nanotubes involves deposition of modifying material - molybdenum disulphide on the surface of the nanotubes from a mixture of thiourea solution and ammonium molybdate in a closed volume for 1-3 days at 180-250°C.

EFFECT: invention simplifies the method of producing material for a field-emission cathode, and obtain material characterised by low electron emission threshold voltage, improved field emission of nanotubes and high density of emission current.

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Description

The invention relates to the field of electronics and nanotechnology, in particular to a method for creating a material for highly efficient field emission cathodes based on carbon nanotubes, which can be used in displays, panel lamps, ionizers, x-ray sources and other technical fields.

Field cathodes made of carbon nanotubes are known in electronics; in comparison with other materials, they have lower operating voltages and a higher emission current density in comparison with other materials used [A.M. Rao, D. Jacques, R. C. Haddon, Kent W. Zhu, C. Bower and S. Jin, In situ-grown carbon nanotube array with excellent field emission characteristics // Appl. Phys. Lett., Vol. 76, No. 25, 2000, pp. 3813-3815].

Various techniques are used in the technique to improve the emission characteristics of field cathodes based on carbon nanotubes.

A known method of processing nanotubes that make up the field cathode, concentrated hydrofluoric acid, including using photoresists. The surface of the nanotube is fluorinated together with the surface of the cathode substrate [Ki Seo Kirn, Je Hwang Ryu, Chang Seek Lee, Jin Jang and Kyu Chang Park, Enhanced and stable electron emission of carbon nanotube emitter arrays by post-growth hydronuoric acid treatment // J Mater Sci: Mater Electron Vol.20, 2009, pp. 120-124 DOI 10.1007 / s10854-007-9463-6]. This leads to a decrease in the work function and a decrease in the threshold voltage for the occurrence of field emission.

A known method of producing metal nanoparticles (for example, cobalt) on the surface of carbon nanotubes, by spraying or chemical deposition to reduce the work function [Seung I. Cha, Kyung T. Kirn, Salman N. Arshad, Chan B. Mo, Kyong H. Lee, and Soon H. Hong, Field-Emission Behavior of a Carbon-Nanotube-Implanted Co Nanocomposite Fabricated from Pearl-Necklace-Structured Carbon Nanotube / Co Powders // Adv. Mater. 2006, 18, 553-558, DOI: 10.1002 / adma.200501267].

A known method of removing a surface layer containing catalytic particles from films of oriented carbon nanotubes [W.-S. Chang, B.-H. Yoo, and S.-N. Cho, Modification of Carbon Nanotube Templates Using Femtosecond Laser Pulse // Japanese Journal of Applied Physics Vol. 47, No. 8, 2008, pp. 6998-7001]. This leads to a decrease in the work function and a decrease in the threshold for field emission.

A known method of producing multilayer structures from carbon nanotubes, for example, by growing single-layer nanotubes on their surface [R. Seelaboyina, S. Boddepalli, K. Noh, M. Jeon and W. Choi, Enhanced neld emission from aligned multistage carbon nanotube emitter arrays // Nanotechnology Vol.19, 2008, 065605], which leads to an increase in the emission current density, decrease in work output and reduce the threshold voltage of the inclusion of electronic emission.

The described methods involve the use of vacuum equipment for plasma-chemical synthesis of nanotubes and surface treatment.

The closest technical solution is a method for producing material for field emission cathodes based on the deposition of LaB ₆ on the tip of a carbon nanotube [W.Wei, K.Jiang, Y.Wei, P.Liu, K.Liu, L.Zhang, Q.Li, and S. Fan, LaB ₆ tip-modined multiwalled carbon nanotube as high quality neld emission electron source // Applied Physics Letters Vol. 89, 2006, 203112]. In this case, the deposition of particles is carried out by spraying LaB ₆ in a specially prepared vacuum chamber on individual nanotubes. Nanotubes modified in this way can be mounted on a metal cathode and used as an electron source.

However, the known method is applicable for processing individual nanotubes. The LaB ₆ layers obtained at the tip of carbon nanotubes are bonded to them only with the help of Van der Waals forces over a small area and do not sit firmly enough on the surface, which can lead to material degradation during cathode operation. Application is carried out in a vacuum chamber using laser spraying and requires expensive equipment.

The objective of the proposed invention is to simplify the method of obtaining field emission cathode material that does not require expensive equipment, and at the same time to obtain material characterized by a lower threshold voltage for switching on electron emission, improving the field emission of the nanotube and allowing to increase the emission current density.

The problem is achieved in that in the method for producing a material for a field emission cathode based on carbon nanotubes, including the deposition of a modifying material on the surface of a nanotube, molybdenum disulfide is used as a modifying material and the modifying material is deposited from a mixture of a solution of thiourea and ammonium molybdate in a closed volume for 1-3 days at 180-250 ° C.

Distinctive features of the invention are: the use of molybdenum disulfide, its precipitation from a mixture of thiourea and ammonium molybdate, conditions of deposition and concentration.

Carbon nanotube field cathodes have lower operating voltages and higher emission current densities than other materials. The material of the cathodes, which include carbon nanotubes, is modified by applying a layer of molybdenum disulfide as a working surface on the surface of the carbon nanotubes. Molybdenum disulfide has a graphite-like structure and is in itself a good electronic emitter [Y. B. Li, Y. Bando, and D. Golberg, MoS ₂ nanoflowers and their neld-emission properties // Appl. Phys. Lett., Vol. 82, No. 12, 2003, pp. 1962-1964]. Application is carried out by the interaction of thiourea with ammonium molybdate under hydrothermal conditions in the presence of nanotubes. The concentrations of the starting components and the solution are selected using calculations taking into account the specific surface of the nanotubes so that the layer of deposited molybdenum disulfide is 1-2 layers (6-18 Å), which is optimal for the cathode material. The conditions for obtaining selected on the basis of general considerations and the theory of hydrothermal reactions. The stated deposition time and deposition temperature are optimal for producing molybdenum disulfide layers. The molybdenum disulfide layer thus obtained on the lateral surface of carbon nanotubes is fixed using van der Waals forces, and the interaction occurs over a large area, which strengthens its bond with the surface.

The use of a molybdenum disulfide layer in the cathode reduces the threshold voltage for switching on electron emission, improves the field emission of the nanotube, and makes it possible to increase the emission current density.

Thus, it is possible to process both finished cathodes and initial nanotubes for subsequent application as cathode material. The material thus obtained can be pressed into the hole of the cathode or fixed by means of a conductive adhesive tape on the surface of the cathode or applied by other methods providing the necessary electrical contact.

Figure 1 shows the image obtained using a high-resolution transmission electron microscope, the initial nanotubes. The image shows a tubular structure and carbon layers of individual nanotubes.

Figure 2 shows the image of the field emission cathode material obtained after the deposition of MoS ₂ on the nanotube surface. Long dark layers of the substance (molybdenum disulfide) located on the outer surface of the nanotube are visible. then the substance stands out in contrast, because it contains heavy atoms - molybdenum disulfide.

Figure 3 shows the current – voltage characteristics of the cathodes, namely, the current – voltage characteristics of the cathode made of the initial carbon nanotubes, –2, the current – voltage characteristics of the cathode containing carbon nanotubes, coated with molybdenum disulfide, –1. For the cathode fabricated using modified carbon nanotubes with molybdenum disulphide, a decrease of occurrence of threshold field intensity field emission (intensity at which the current reaches 10 a ^-7), and also increase the current density at about otherness electric fields.

Figure 4 shows the current – voltage curves in the Fowler – Nordheim coordinates for cathodes made from the initial carbon nanotubes, –2, and the proposed material containing carbon nanotubes coated with molybdenum disulfide, –– 1. In this representation, the slope of the straight line approximating the volt the ampere characteristic is proportional to φ ^3/2 / β, where φ is the work function of the electrons from the material, and β is the electric field gain in the material. From these dependences it follows that the work function of the electrons from the cathode material, consisting of carbon nanotubes modified with molybdenum disulfide layers, is lower than from the initial carbon nanotubes.

Thus, it is possible to process both finished cathodes and source nanotubes for subsequent application as cathode material. The material thus obtained can be pressed into the hole of the cathode or fixed by means of a conductive adhesive tape on the surface of the cathode or applied by other methods providing the necessary electrical contact.

Typical example

The initial carbon nanotubes obtained by a known method of chemical vapor deposition of a carbon source in the presence of a catalyst, or carbon nanotubes deposited on a substrate are placed in a closed volume (autoclave) and an aqueous solution containing thiourea and ammonium molybdate is poured into this volume, in amounts necessary for the formation of a monolayer or bilayer of molybdenum disulfide on the surface of carbon nanotubes. The mixture is heated to a predetermined temperature, for example 235 ° C., and is held for a certain time, for example 2.5 days. After exposure, the mixture is cooled. The resulting product is filtered. The resulting material is carbon nanotubes, the surface of which is covered with a layer of molybdenum disulfide with a thickness of 6-18 Å.

Thus, the proposed method can be processed source nanotubes for subsequent application as a cathode material. The application of carbon nanotubes thus treated can be carried out by pressing them into the hole of the cathode or by fixing them to the surface of the cathode, for example, by means of a conductive adhesive tape or by other methods providing the necessary electrical contact.

Claims (1)

A method of producing a material for a field emission cathode based on carbon nanotubes, including the deposition of a modifying material on the surface of a nanotube, characterized in that molybdenum disulfide is used as a modifying material and the precipitation of the modifying material is carried out from a mixture of a solution of thiourea and ammonium molybdate in a closed volume for 1-3 days at 180-250 ° C.

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