1. Field of the Invention
The present invention relates to a deposit molding method by which an gaseous organic metal is decomposed by irradiation with an electron beam to form a deposit, and to a submicron size metal deposit apparatus capable of carrying out the molding method.
2. Background Art
A method is known whereby, a gaseous organic metal is irradiated with a gallium ion, which is a kind of a charged particle, in order to decompose the same, thereby forming a metal deposit in an irradiated area. Another method of forming a similar metal deposit by electron beam irradiation has also been reported.
For example, it is reported in Digest 30a-YD-4 of the 64th Annual Meeting of the Japan Society of Applied Physics that a dot with a minimum diameter of about 3.5 nm was molded with an electron beam of about 0.8 nm in probe size, using a scanning transmission electron microscope. In this case, the accelerating voltage of the electron beam is 100 kV or more.
Non-Patent Document 1: Kazuo Furuya “Current State of Making of Nanostructures Using a Focused Electron Beam” 30a-YD-4 of the 64th Annual Meeting of the Japan Society of Applied Physics
In experiments to mold a metal deposit with the energy of the electron beam ranging from several kV to dozens of kV, although the formation of a metal deposit was confirmed, the metal deposit was amorphous and significantly inferior in conductivity, strength, and weldability. It was also learned that when the amorphous metal deposit was heated after the molding thereof, hydrocarbon that had mixed in reacted with metal to form metal carbide or metal-hydrocarbon compound, so that desired characteristics could not be obtained.
Further, in semiconductor device inspection where devices are inspected using a tungsten probe, the tungsten probe requires frequent replacement because of damage.
A first object of the present invention is to provide a method for obtaining a metal deposit that is superior in conductivity, strength, and weldability.
A second object of the present invention is to provide a method for forming a terminal that is suitable for a conductive probe.
In a first means to achieve the first object, the invention provides a method by which a small amount of gaseous organic metal is filled into a vacuum atmosphere, and the gaseous organic metal is decomposed by irradiation with an electron beam, thereby depositing metal components on a beam-irradiated portion. The deposition is conducted while irradiating the deposited-portion with a laser.
In a second means to achieve the first object, the invention provides a method by which, while a small amount of gaseous organic metal is filled into a vacuum atmosphere, the gaseous organic metal is decomposed by irradiation with an electron beam, and metal components are deposited on a beam-irradiated portion. A heater is brought close to the deposited portion either from above or below a substrate, thereby providing the deposited portion with thermal radiation from the heater.
In a third means to achieve the first object, the invention provides a method by which, while a small amount of gaseous organic metal is filled into a vacuum atmosphere, the gaseous organic metal is decomposed by irradiation with an electron beam, thereby depositing metal components on the beam-irradiated portion. An infrared lamp is disposed above a substrate to provide the metal components with thermal radiation of infrared rays condensed by a concave mirror disposed in the rear of the infrared lamp.
In a fourth means to achieve the first object, the energy of the electron beam is controlled to range from 1 kV to dozens of kV in the first and second means to achieve the first object.
In a first means to achieve the second object, the conductivity of the deposit is controlled to be 1 μA or more in the first and second means to achieve the first object.
In a second means to achieve the second object, the bonding strength of the deposit is controlled to be 1 nN or more, or the deposit is rendered such that it permanently resists deformation, in the first and second means to achieve the first object.
According to the present invention, hydrocarbon contamination can be prevented during the electron beam irradiation, so that a crystalline metal deposit superior in conductivity, strength, and weldability can be molded.
For example, when depositing tungsten by irradiation with an electron beam, a reaction of decomposition, W(CO)6→W+6CO↑, is used. It has been learned that if the accelerating voltage of the electron beam is several kV to dozens of kV, the resultant deposit is mainly amorphous, and that this is due to contamination by hydrocarbon residue inside an electron beam apparatus. This problem is solved by a means whereby, in a process of metal deposit molding, crystallization of metal deposition is facilitated while preventing the introduction of hydrogen.
Number | Date | Country | Kind |
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2003-342925 | Oct 2003 | JP | national |