Electrolysis: processes – compositions used therein – and methods – Electrolytic coating – Utilizing electromagnetic wave energy during coating
Reexamination Certificate
2000-05-16
2002-04-02
Wong, Edna (Department: 1741)
Electrolysis: processes, compositions used therein, and methods
Electrolytic coating
Utilizing electromagnetic wave energy during coating
Reexamination Certificate
active
06365027
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to methods for forming an electrodeposited film or an electrode over the surface of an object to be treated using an ultra-short pulse laser.
2. Description of the Related Art
Attempted applications of laser to electrode formation technology can be broadly classified into plating and etching.
The basic principle of application to plating is that an object to be plated soaked in a plating solution is irradiated with a laser beam and the resultant thermo-electromotive force causes part of the object to be plated (see, for instance, Reference 1: specification of the U.S. Pat. No. 4,349,583, and Reference 2: IBM
J. Res. Develop.,
Vol. 42, No. 5, September 1998).
According to this plating method, a bias voltage may or may not be applied from an external circuit. Application of a bias voltage would result in electrolytic plating, which allows partial plating as the laser-irradiated part is plated faster than the non-irradiated part. Non-application of a bias voltage would result in non-electrolytic plating. In this case, the laser-irradiated part functions as the active electrode and the non-irradiated part, as the opposite electrode, and the plating of the irradiated part and the dissolution (etching) of the non-irradiated part take place at the same time.
The above-cited specification of the U.S. Pat. No. 4,349,583, for example, discloses a case of non-electrolytic plating. Referring to this prior art,
FIG. 13
illustrates a case in which a less noble metal (LNM) substrate disposed in a plating bath is irradiated with a laser beam LB and a more noble metal (MNM) electrode is formed by metal-plating over the LNM substrate, while
FIG. 14
shows an instance in which an LNM film over a glass substrate G is irradiated with the laser beam LB and an MNM electrode is formed by metal-plating over the LNM film.
Since FIG.
13
and
FIG. 14
illustrate cases non-electrolytic plating involving no application of a bias voltage, in both cases LNM portions around the MNM part are etched simultaneously with the formation of metal-plating as an MNM electrode (see the ADR portion in FIG.
13
and the L portion in FIG.
14
).
As applications of the above-described plating technique using laser irradiation, maskless patterning and electrode repairing are proposed.
Incidentally, the laser so far considered for application to plating is either a continuous beam (in the case of the U.S. patent of Reference 1), such as an argon laser, or a pulse laser, whose time width is tens of picoseconds or more, such as a YAG laser.
Since these lasers, in order to obtain a sufficient thermo-electromotive force, require a high output of 10
2
to 10
6
W/cm
2
in the intensity of irradiating light, plating over a large area needs either a high output laser or long duration of irradiation.
There is another problem in the conventional application to plating that, since it is a thermal process, thermal diffusion gives rise to overhangs on the edges of plating as illustrated in FIG.
13
and FIG.
14
.
Furthermore, for electrode formation, in many cases a hole is first bored by etching followed by electrode formation (plating) in the bored part, but since no sharply edged hole can be bored by similar thermal diffusion with a continuous beam and a pulse of tens of picoseconds in time width, different lasers need to be used for etching and electrode formation.
In view of these problems, this invention is intended to provide methods which permit formation of efficient electrodes consuming less energy and excelling in quality.
SUMMARY OF THE INVENTION
To solve the above-noted problems, according to one aspect of this invention, there is provided a method for electrodeposited film formation by which a surface of an object to be treated, the surface at least permitting generation of charged particles when irradiated with a laser beam, is irradiated with a pulse laser whose pulse width is less than a picosecond; almost solely electrons are excited on the surface of the object to be treated to generate a state of non-equilibrium in either temperature or energy between the electrons and a grid; and an electrodeposited film is formed on the surface of the object to be treated using the electrons excited in that state of non-equilibrium.
According to another aspect of the invention, there is provided a method for electrodeposited film formation by which a surface of an object to be treated, the surface at least permitting generation of charged particles when irradiated with a laser beam, is irradiated with a pulse laser whose pulse width is less than a picosecond; and an electrodeposited film is formed on the laser-irradiated part of the surface of the object to be treated using hot electrons generated by this laser irradiation.
According to still another aspect of the invention, there is provided a method for electrodeposited film formation, as stated in the foregoing paragraph, wherein the object to be treated is a substrate, and an electrode is formed as the electrodeposited film by metal-plating the surface of the substrate using a pulse laser whose pulse width is less than a picosecond.
According to yet another aspect of the invention, there is provided a method for electrodeposited film formation, as stated in the foregoing paragraph, wherein the electrodeposited film is formed by applying a bias voltage so as to inject electrons into the surface of the object to be treated when carrying out the metal-plating with the pulse laser whose pulse width is less than a picosecond.
REFERENCES:
patent: 4217183 (1980-08-01), Melcher et al.
patent: 4349583 (1982-09-01), Kulynych et al.
Gutfeld et al., “Electrochemical Microfabrication by Laser-Enhanced Photothernal Processes”, J. Res. Develop., vol. 42, No. 5, pp. 639-652. Sep. 1998.*
Chichkov et al., Fetosecond, picosecond and nanosecond laser ablation of solids, Applied Physics A-63, 1996, pp. 109-115, no month available.
Obara et al.,Laser Engineering Optics, Kyoritsu Shuppan, 1998, pp. 130-133, no month available.
Pu Lyong Sun
Sato Yasuhiro
Tatsuura Satoshi
Tian Minquan
Fuji 'Xerox Co., Ltd.
Oliff & Berridg,e PLC
Wong Edna
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