JP4500926B2 - Fine line drawing method - Google Patents

Description

  The present invention relates to a fine line drawing method, and more particularly to a fine line drawing method used for fine processing technology, surface mounting technology, electrodes, and wiring.

In a normal inkjet (piezo method or bubble jet method), the minimum discharge liquid amount is said to be about 2 picoliters (pl). This corresponds to a diameter of about 16 μm when the droplet is assumed to be spherical. After landing on glass or a silicon substrate, the dot diameter becomes about several tens to 100 μm. The landing error is also about 30 μm. For this reason, it has been difficult to write a thin line using a conventional ink jet apparatus.
This may be due to the poor landing accuracy, the amount of liquid per drop, and the formation of microbulges by surface tension on the substrate.

As a conventional ink jet recording method, continuous recording (continuous recording is performed by ultrasonically oscillating and ejecting ink from a nozzle in the form of droplets, charging the flying ink droplets, and deflecting them with an electric field) For example, see Patent Document 1), as a drop-on-demand method for ejecting ink droplets in a timely manner, an electric potential is applied between the ink ejection unit and the recording paper, and the ink droplets are drawn out from the ink ejection opening by electrostatic force, onto the recording paper. Known is an electrostatic attraction method (for example, see Patent Documents 2 to 3), a heat conversion method (for example, see Patent Document 4) such as a piezo conversion method or a bubble jet (registered trademark) method (thermal method), and the like. Yes.
Further, a raster scanning method for displaying a single image using scanning lines has been used as a drawing method of a conventional ink jet apparatus.

However, the above-described conventional inkjet recording method has the following problems.
(1) It is difficult to eject ultrafine droplets In an inkjet method (piezo method or thermal method) that is currently in practical use and widely used, it is difficult to eject a minute amount of liquid that is less than 1 pl. This is because the pressure required for ejection increases as the nozzle becomes finer.
In the electrostatic suction method, for example, the nozzle inner diameter described in Patent Document 2 is 0.127 mm, and the nozzle diameter described in Patent Document 3 is 50 to 2000 μm, preferably 100 to 1000 μm, and 50 μm. It was considered impossible to discharge the following ultrafine droplets.
As will be described later, in the electrostatic attraction method, in order to realize fine droplets, extreme precision is required for controlling the driving voltage.
(2) Insufficient landing accuracy The kinetic energy imparted to the droplet discharged from the nozzle decreases in proportion to the cube of the droplet radius. For this reason, fine droplets cannot secure sufficient kinetic energy to withstand air resistance, and accurate landing cannot be expected due to air convection. Furthermore, as the droplet becomes finer, the effect of surface tension increases, so the vapor pressure of the droplet increases and the amount of evaporation increases. For this reason, fine droplets cause a significant loss of mass during flight, and it is difficult to maintain the shape of the droplets upon landing.
As described above, miniaturization of droplets and high accuracy of the landing position are conflicting problems, and it has been difficult to realize both at the same time.
This poor landing position accuracy not only deteriorates the print image quality, but also becomes a serious problem when, for example, a circuit wiring pattern is drawn using a conductive ink by an inkjet technique. That is, the poor position accuracy can not only draw a wiring with a desired thickness, but can even cause a disconnection or a short circuit.

Therefore, as a device for writing a thin line with a conventional ink jet, a method of performing patterning on a substrate in advance is known. For this purpose, by using a technique such as photolithography, a new liquid or liquid-liquid area is patterned in advance on the substrate, a three-dimensional wall called a bank is provided, and a lyophilic treatment is performed on the bank. Thus, a method for aligning landing droplets on a substrate has been devised and performed.
However, when connecting lines at right angles, there are also known phenomena in which microbulges are formed by the surface tension effect and liquid concentrates at the bending point (see, for example, Patent Document 5).

By using an ultrafine inkjet recently developed by the inventors, it is possible to draw fine lines of less than 10 μm by taking advantage of the good landing accuracy and the features of fine droplets. However, in order to write a line without a break due to a small dot diameter, the linear velocity needs to be 1/10 or less. When drawing at a reduced linear velocity, the line width tends to increase or a microbulge tends to be formed, as in the case of drawing with a normal ink jet. (For example, refer nonpatent literatures 1 and 2).
Also, because of the fine droplets, it is necessary to draw repeatedly to some extent in order to ensure the thickness. For these reasons, there has been room for further improvement in throughput reduction in thin line drawing using ultra-fine inkjet.
Japanese Patent Publication No.41-16773 Japanese Patent Publication No. 36-13768, JP 2001-88306 A Japanese Patent Publication No. 61-59911 JP 2003-142802 A H. Gau, et al., Science, 1999, Vol. 283, p. 46 ADA Darhuber, et al., Journal of Applied Physics, 2000, Vol. 87, No. 11, p. 7768

  It is an object of the present invention to provide a fine line drawing method which eliminates fine line breaks, improves wettability, improves throughput, and narrows the line width.

Overcoming the conflicting problem of drawing fine and continuous fine lines while ensuring a certain degree of throughput by inkjet, for two or more stages of application, that is, for pre-drawing for electric field concentration and for mass application of target substances This was realized by dividing into subsequent drawing.
That is, the present invention is (1) by applying an electric field to the nozzle, ejecting fine droplets of a material capable of producing electric field concentration onto a substrate by the previous drawing that turn into fixed landed the droplets to the substrate to form fine patterns, followed by a fine droplets by utilizing the electric field concentration discharged from the nozzle, by flying, and wherein performing the present portrayal by landing the fine droplets on the fine pattern Fine line drawing method,
(2) The fine pattern according to (1), wherein the pre-drawing draws a fine pattern having a line width of 10 μm or less, and a droplet amount in the main drawing is larger than a droplet amount in the pre-drawing. Line drawing method, and
(3) (1) or (2) is intended to provide a fine thin line pattern characterized in that obtained by fine line drawing method according to claim.

The method of the present invention can eliminate fine line breaks, improve wettability, improve throughput, and obtain a fine line pattern with a narrow line width.
Further, according to the present invention, it is possible to draw a fine wiring with resource saving, energy saving, high throughput and high definition. In addition, the line width can be reduced, the thickness can be ensured, the gap can be reduced, the line width can be made uniform, and the discharge can be stabilized.

The present invention uses an electric field to cause a microfluid made of a material capable of causing electric field concentration to fly and adhere to a substrate, and to make a pre-drawing (pre-patterning) by utilizing the quick drying and high-speed solidification of fine droplets. or, performing also referred) and pre-drawn to form a fine pattern (seed), followed by on the fine pattern, using an electric field, and performs the portrayal of flying attaching microfluidic, the drawing The amount of liquid can be increased by drawing, and the wiring can be made seamless.
Examples of the substrate used in the present invention include glass, metal (copper, stainless steel, etc.), semiconductor (silicon), polyimide, polyethylene terephthalate, and the like.

The pre-drawing is preferably performed by discharging fine droplets using an ultrafine ink jet. The microdroplet has an extremely high evaporation rate due to the effect of surface tension and the high specific surface area. Therefore, the microdroplet is fixed immediately after landing. The liquid amount per droplet to be deposited by flying in the pre-drawing is preferably 1 pl (picoliter) or less, more preferably 0.1 pl or less, and even more preferably 10 fl (femtoliter) or less. Further, the dot diameter upon landing is preferably 10 μm or less, and more preferably 1 μm or less.
The drawing speed is preferably 10 μm / sec to 1 mm / sec, more preferably 100 μm / sec to 1 mm / sec. The line drawn at this time may have an interval between dots, and is not necessarily a line. The line width drawn by the first drawing is preferably 10 μm or less, and more preferably 0.1 to 5 μm. Note that the drawing speed V is preferably in the range of about 10 times or less of f × d, more preferably about 1 time.
The apparatus for performing the first drawing is not limited to the ultra fine ink jet, but it is preferable to use the ultra fine ink jet from the viewpoint of the landing accuracy and the fine liquid amount.

The material of the fine fluid used for the pre-drawing is a material that causes electric field concentration, and a paste containing ultrafine metal particles is preferable. The metal species of the paste preferably used in the present invention is not limited thereto, but silver or gold is preferable.
In addition, a polymer (such as an ethanol solution of polyvinylphenol), a conductive polymer (such as PEDOT / PSS), and the like can be used as the first drawing material.
In the present invention, “electric field concentration” means the following state. That is, an electric field is generated on the substrate surface by the voltage applied to the nozzle. If the dielectric constant of the liquid material and what it solidifies is higher than that of the substrate material, when the droplets land on and adhere to the substrate, the density of the electric lines of force through the liquid will be greater than that of the unattached substrate portion. Get higher. This state is called a state where electric field concentration has occurred on the substrate. Since it is considered that the droplets fly along the lines of electric force and are attracted to the portion with the highest density, the droplets flying later will preferentially land on the pre-drawing portion.

Subsequently, on the fine patterns formed on a substrate, using an electric field, conduct the portrayal of flying deposited fine fluid. Preferably, is performed was more than the droplet amount present drawing in Saki描image the droplet amount. The apparatus that performs this drawing can be used as it is or after changing the nozzles as appropriate. For example, in an electrostatic attraction type ultrafine fluid jet, droplets fly due to the mirror image force of the charged fluid, but if there is a pattern on the substrate by pre-drawing, the electric field tends to concentrate at the patterning location. The fluid can easily fly to the drawn point. Due to this effect, liquid breakage is less likely to occur and landing accuracy is greatly improved.

Here, the fine fluid material for the main drawing and the previous drawing may be the same or different. For example, it is conceivable to use a fluid material with good frequency characteristics for the previous drawing, draw a line at high speed, and draw the target material in the subsequent main drawing. In this drawing, a material can be appropriately selected according to the intended function and the like.
Further, the previous drawing and the main drawing may be performed using the same nozzle, or different nozzles may be used. Further, the first drawing and the main drawing may be performed on the same stage or may be performed on different stages.

  It is preferable that the droplet amount in the main drawing is larger than the droplet amount in the previous drawing. In the present drawing, the amount of liquid to be deposited by flying is preferably 10 fl to 10 pl, more preferably 10 fl to 1 pl. The drawing speed is preferably 10 μm / sec to 1 mm / sec, more preferably 100 μm / sec to 1 mm / sec.

In the present invention, preferably, Saki描picture, both the portrayal, with ultra-fine inkjet, is performed by ejecting fine droplets. Microdroplets have an extremely high evaporation rate due to the effect of surface tension and the high specific surface area. Further, since the electric field concentrates on the patterning portion by the previous drawing, the discharge fluid is concentrated. Due to this effect, patterning is performed efficiently in this drawing.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a conceptual diagram of the drawing method of the present invention. 1 is a nozzle and 13 is a substrate. FIG. 1A is a conceptual diagram of the previous drawing. A fine pattern is formed on the substrate 13 by flying and adhering a fine fluid of a material that causes electric field concentration from the nozzle 1 to the substrate 13. FIG. 5B is a conceptual diagram of the first drawing + the main drawing (post drawing). The fine lines formed by this drawing have a small wetting spread. FIG. 3C is a conceptual diagram when only the main drawing is performed. The fine lines formed here have a large wetting spread. Here, the same nozzle may be used for the first drawing and the main drawing, or separate nozzles, that is, the first drawing fine nozzle and the main drawing thick nozzle may be used, or the same nozzle. The discharge amount may be controlled by changing only the parameter using.

(Method of realizing low drive voltage and small amount of discharge)
FIG. 2 is a partial cross-sectional view showing an example of an ultrafine ink jet used in the present invention.
In the figure, reference numeral 1 denotes an ultrafine nozzle. In order to realize an ultrafine droplet size, it is preferable to provide a low-conductance flow path in the vicinity of the nozzle 1 or make the nozzle 1 itself have a low-conductance. For this purpose, a glass microcapillary tube is suitable, but a conductive substance coated with an insulating material is also possible. The reason why the nozzle 1 is preferably made of glass is that a nozzle of about several μm can be easily formed, that the nozzle end can be regenerated by crushing the nozzle end, and in the case of a glass nozzle, the taper is tapered. This is because the electric field is easily concentrated on the tip of the nozzle because it is angled, and because it has moderate flexibility, it is easy to form a movable nozzle. The low conductance is preferably 10 ⁻¹⁰ m ³ / s or less. In addition, the low conductance shape is not limited thereto, but, for example, a structure in which the inner diameter of a cylindrical flow path is reduced or the flow resistance is provided inside even if the flow path diameter is the same. Or a shape in which a valve is provided.

  For example, a cored glass tube (manufactured by Narishige Co., Ltd., GD-1 (trade name)) can be used as a nozzle, and can be created by a capillary puller. By using the cored glass tube, the following effects can be obtained. (1) Since the core side glass is easily wetted with ink, ink filling becomes easy. (2) Since the core side glass is hydrophilic and the outer glass is hydrophobic, the area where the ink is present is limited to the inner diameter of the core side glass at the nozzle end, and the electric field concentration effect becomes more prominent. . (3) A fine nozzle can be realized. (4) A sufficient mechanical strength can be obtained. However, the core is not essential, and a normal glass capillary can be used without any problem.

  In the ultrafine inkjet used in the present invention, the lower limit value of the nozzle diameter is 0.01 μm in production, and the upper limit value of the nozzle diameter is the nozzle diameter when the electrostatic force exceeds the surface tension. And 25 μm from the upper limit of the nozzle diameter when the discharge condition is satisfied by the local electric field strength. The upper limit of the nozzle diameter is more preferably 15 μm for effective discharge. In particular, in order to more effectively use the local electric field concentration effect, the nozzle diameter is desirably in the range of 0.01 to 8 μm. The nozzle 1 is not limited to a capillary tube, and may be a two-dimensional pattern nozzle formed by fine processing.

When the nozzle 1 is made of glass with good moldability, the nozzle cannot be used as an electrode, so two metal wires (for example, tungsten wires) are inserted into the nozzle 1 as electrodes. The electrode may be formed by plating in the nozzle. When the nozzle 1 itself is formed of a conductive material, an insulating material is coated thereon.
The nozzle 1 is filled with a solution 3 to be discharged. At this time, the electrode 2 is disposed so as to be immersed in the solution 3. The solution 3 is supplied from a solution source (not shown). Examples of the solution 3 include ink. The nozzle 1 is attached to the holder 6 by a shield rubber 4 and a nozzle clamp 5 so that pressure does not leak.

Reference numeral 7 denotes a pressure regulator, and the pressure adjusted by the pressure regulator 7 is transmitted to the nozzle 1 through the pressure tube 8.
The nozzle, electrode, solution, shield rubber, nozzle clamp, holder and pressure tube are shown in a side sectional view. A substrate 13 is disposed by a substrate support 14 in the vicinity of the tip of the nozzle.
The role of the pressure regulator in the present invention can also be used to push the fluid out of the nozzle by applying high pressure, but rather adjust the conductance, fill the nozzle with the solution, remove the nozzle clog It is particularly effective for use in such applications. It is also effective for controlling the position of the liquid level and forming a meniscus. It also plays a role of controlling the minute discharge amount by controlling the force acting on the liquid in the nozzle by adding a phase difference with the voltage pulse.
Reference numeral 9 denotes a computer, and an ejection signal from the computer 9 is sent to and controlled by an arbitrary waveform generator 10.

  The arbitrary waveform voltage generated from the arbitrary waveform generator 10 is transmitted to the electrode 2 through the high voltage amplifier 11. The solution 3 in the nozzle 1 is charged by this voltage. This increases the concentrated electric field strength at the tip of the nozzle.

In this ultrafine ink jet, as shown in FIG. 3, the electric field concentration effect at the tip of the nozzle and the liquid droplets are charged by the electric field concentration effect. Use the action. Therefore, it is not necessary to make the substrate 13 or the substrate support 14 conductive or to apply a voltage to the substrate 13 or the substrate support 14 as in the prior art. That is, as the substrate 13, an insulating glass substrate, a plastic substrate such as polyimide, a ceramic substrate, a semiconductor substrate, or the like can be used. Further, by increasing the concentration electric field strength concentrated on the nozzle tip, the applied voltage is reduced. Further, the voltage applied to the electrode 2 may be either plus or minus.
FIG. 3 schematically shows a state in which conductive ink is injected into a nozzle having a diameter d and is positioned perpendicular to the height of h from the infinite flat plate conductor. R indicates a direction parallel to the infinite flat conductor, and Z indicates a Z-axis (height) direction. L indicates the length of the flow path, and ρ indicates the radius of curvature. Q is the charge induced at the nozzle tip. Q ′ is a mirror image charge having an opposite sign induced at a symmetrical position in the substrate.

  The closer the distance between the nozzle 1 and the substrate 13 is, the closer the mirror image force acts, so that the landing accuracy is improved. On the other hand, in order to discharge onto a substrate having an uneven surface, a certain distance is required to avoid contact between the uneven surface on the substrate and the nozzle tip. Considering the landing accuracy and the unevenness on the substrate, the distance between the nozzle 1 and the substrate 13 is preferably 500 μm or less, and when the unevenness on the substrate is small and the landing accuracy is required, it is preferably 100 μm or less, and more preferably 30 μm or less. More preferred. Although not shown, feedback control based on nozzle position detection is performed to keep the nozzle 1 constant with respect to the substrate 13. Further, the substrate 13 may be placed and held on a conductive or insulating substrate holder.

  FIG. 4 shows the applied voltage dependence of the print dot diameter (hereinafter, the diameter may be simply referred to as the diameter) in an example of the ultrafine inkjet used in the present invention. As the printing dot diameter d, that is, the nozzle diameter becomes smaller, the discharge start voltage V, that is, the drive voltage, has decreased. As is clear from FIG. 4, ejection was possible at a low voltage much lower than 1000V. When a nozzle having a diameter of about 1 μm was used, the driving voltage decreased to the 200V level. The dot diameter can be controlled by voltage. It can also be controlled by adjusting the pulse width of the applied voltage pulse.

(Clogging prevention and release)
For cleaning the tip of the nozzle 1, a high pressure is applied to the nozzle 1, the substrate 13 is brought into contact with the tip of the nozzle 1, and the solidified solution is rubbed against the substrate 13. This is performed by utilizing a capillary force acting on a slight gap between the nozzle 1 and the substrate 13.
In addition, the nozzle 1 is immersed in a solvent before filling with the solution, and a small amount of the solvent is filled into the nozzle 1 by capillary force, thereby preventing the first nozzle from being clogged. Further, when clogging occurs during printing, it can be removed by immersing the nozzle in a solvent.
It is also effective to immerse the nozzle 1 in a solvent dropped on the substrate 13 and simultaneously apply pressure, voltage, and the like. Although it cannot be said depending on the type of the solution used, it is generally effective for a low vapor pressure, high boiling point solvent such as tetradecane.
In addition, as will be described later, by using alternating current drive as a voltage application method, the solution in the nozzle is stirred and kept homogeneous, and when the chargeability of the solvent and the solute is significantly different, the average of the solution By alternately ejecting droplets with excess solvent and solute excess than the composition, nozzle clogging is alleviated. In addition, by optimizing the charging characteristics, polarity, and pulse width of the solvent and solute in accordance with the properties of the solution, the time variation of the composition was minimized and stable ejection characteristics could be maintained for a long time.

(Drawing position adjustment)
Although it is practical to place a substrate holder on the XYZ stage and manipulate the position of the substrate 13, the nozzle 1 is placed on the XYZ stage. It is also possible. The nozzle-substrate distance is adjusted to an appropriate distance using a position fine adjustment device. In addition, the nozzle position can be kept constant with an accuracy of 1 μm or less by moving the Z-axis stage by closed loop control based on the distance data from the laser rangefinder.

(Scanning method)
In the conventional raster scan method, when continuous lines are formed, wiring may be interrupted due to insufficient landing position accuracy or ejection failure. Therefore, in the present invention, it is preferable to adopt a vector scan method in addition to the raster scan method. For circuit drawing itself by vector scanning using a single-nozzle inkjet, see, for example, Fuller et al., Journal of Microelectromechanical systems, Vol. 11, no. 1, P.I. 54 (2002).
As the vector scan method, a method used in a normal plotter can be used as appropriate.
For example, using SGSP-20-35 (XY) made by Sigma Koki and Mark-204 controller as the stage used, and using Labview made by National Instruments as control software, the stage is moved by itself. Consider a case where the speed is adjusted so as to obtain the best drawing within the range of 1 μm / sec to 1 mm / sec. In this case, in the case of raster scanning, the stage can be driven at a pitch of 1 μm to 100 μm and linked with the movement, and ejection can be performed by voltage pulses. In the case of vector scanning, the stage can be moved continuously based on vector data.

(Drawing with ultra-fine inkjet)
Since the droplets used in the present invention are ultrafine, depending on the type of solvent used in the ink, the droplets instantly evaporate upon landing on the substrate, and the droplets are instantaneously fixed in place. The drying speed at this time is orders of magnitude faster than the speed at which droplets having a size of several tens of μm are dried by the conventional technique. This is because the vapor pressure becomes extremely high due to the finer droplets. In the prior art using a piezo method or the like, it is difficult to form such fine dots and the landing accuracy is poor, and therefore, hydrophilic and hydrophobic patterning is performed in advance on the substrate as a countermeasure (for example, S. Shillinghouse et al., Science, Vol. 290, 15 December (2000), 2123-2126). In this method, since preliminary processing is required, there is a problem that the advantage of the ink jet method that printing can be directly performed on the substrate is impaired. In the present invention, by adopting such a method, the positional accuracy can be further improved. It is also possible to improve.

  Moreover, a fine three-dimensional structure of ultrafine metal particles can be formed by ultrafine ink jet. For example, metallic silver ultrafine particles (nano paste: manufactured by Harima Chemicals) can be drawn at intervals of 30 μm with a diameter of 0.6 μm. Nanopaste is an independent dispersion of ultrafine particles with a particle size of several nanometers, with special additives added. At room temperature, the particles do not bond with each other, but are slightly lower than the melting point of the constituent metals by raising the temperature slightly. Sintering occurs at temperature. After drawing, heat treatment can be performed at about 200 ° C. to form a three-dimensional structure of silver. In the present invention, the “three-dimensional structure” refers to a structure having a dimension in the thickness direction that is about three times or more of the value compared to the shorter dimension (minor axis) of the bottom surface. As an example, a cylindrical shape, an elliptical column, or a projected shape from above includes a linear shape having a thickness that is significantly larger than the line width (more than 3 times the line width).

Fine line drawing of the following Examples 1-3 was performed by making nano paste fluid fly little by little from the acicular electrode of an ultrafine inkjet, and making it adhere to a board | substrate. The frequency of the pre-drawing was 1 KHz when gold nanopaste was used, and 10 Hz when silver nanopaste was used. The drawing speed was 1 mm / sec, and the applied voltage was 500V. On the other hand, the stage moving speed of this drawing was 0.1 mm / sec, and the applied voltage was 1000V. The frequency was the same as the previous drawing. In this case, the amount of liquid droplets by this drawing was about 10 times per one droplet compared to the amount of liquid droplets of the previous drawing.
Example 1
Fine line drawing was performed on a glass substrate using silver nanopaste. As a result, a photograph of the pattern example formed is shown in FIG. FIG. 5A is a first drawing (first drawing), FIG. 5B is a first drawing + main drawing (one previous drawing, one main drawing), and FIG. 5-3 is a main drawing only (one main drawing). It is an example. 5A to 5C, the position on the substrate and the magnification are the same.
Clearly, there was a significant difference in line width with and without predrawing. The fine line pattern with the pre-drawing (FIG. 5-2) has a line width of about 1/2 and less wet spread than the fine line pattern without the drawing (FIG. 5-3). This is suitable for wiring applications that require a narrow line width and thickness.

Example 2
Fine lines were refracted on a glass substrate using gold nanopaste. As a result, a photograph of the formed pattern is shown in FIG. FIG. 6A shows the first drawing (first drawing once), FIG. 6B shows the first drawing + main drawing (one previous drawing, once main drawing), and FIG. 6-3 shows the main drawing only (one main drawing). It is an example. 6A to 6C, the position on the substrate and the magnification are the same.
Clearly, there was a significant difference in line width with and without predrawing. That is, the thin line pattern without the pre-drawing has a narrowed line, and the line width is not uniform and tends to be broken (FIG. 6-2), whereas the thin line pattern with the pre-drawing has a uniform line width. Thus, there is no problem of interruption despite drawing at the same frequency (FIG. 6-3).

Example 3
Using gold nanopaste, fine line refraction drawing was performed on a glass substrate with the number of previous drawing and main drawing being two. As a result, a photograph of the formed pattern is shown in FIG. FIG. 7-1 shows the pre-drawing (pre-drawing twice), FIG. 7-2 shows the pre-drawing + main drawing (pre-drawing twice, main drawing two times), and FIG. 7-3 shows the main drawing only (two times of main drawing). It is an example. 7A to 7C, the position on the substrate and the magnification are the same.
Increasing the number of drawing operations alleviates the instability of the line width as seen in FIG. 6-3, but the line width is clearly increased (FIG. 7-3). On the other hand, the narrowness of the line width is maintained for the previously drawn image (FIG. 7-2).

  According to the present invention, since both throughput and fine wiring can be achieved, it is particularly useful for applications such as wiring drawing in the field of surface mounting technology, but other high-quality printing quality is desired. And generally applicable.

It is a schematic explanatory drawing of the drawing method of this invention. It is explanatory drawing which shows an example of the ultra fine inkjet used for this invention. It is a schematic diagram shown in order to demonstrate calculation of the electric field strength of a nozzle in the ultrafine inkjet used for this invention. It is a graph which shows the applied voltage dependence of the ultra fine inkjet used for this invention. 2 is a photograph of a pattern (first drawing) formed in Example 1. FIG. 2 is a photograph of a pattern (first drawing + final drawing) formed in Example 1. FIG. 2 is a photograph of a pattern (main drawing) formed in Example 1. FIG. 6 is a photograph of a pattern (first drawing) formed in Example 2. FIG. 6 is a photograph of a pattern (first drawing + main drawing) formed in Example 2. FIG. 4 is a photograph of a pattern (main drawing) formed in Example 2. FIG. 6 is a photograph of a pattern (first drawing) formed in Example 3. FIG. 6 is a photograph of a pattern (first drawing + main drawing) formed in Example 3. FIG. 6 is a photograph of a pattern (main drawing) formed in Example 3. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Nozzle 2 Electrode 3 Solution 4 Shield rubber 5 Nozzle clamp 6 Holder 7 Pressure regulator 8 Pressure tube 9 Computer 10 Arbitrary waveform generator 11 High voltage amplifier 13 Substrate 14 Substrate support

Claims (3)

By applying an electric field to the nozzle, ejecting fine droplets of a material capable of producing electric field concentration, the droplets to form a fine pattern on a substrate by previously drawn that turn into fixed landed on the substrate, followed by ejected from the nozzle fine droplets by utilizing the electric field concentration Te, by flying fine line drawing wherein by performing the portrayal by landing the fine droplets on the fine pattern. It said previous drawing, the line width is drawn to the following fine pattern 10 [mu] m, the droplet amount in the present drawing, fine fine line drawing method according to claim 1, wherein the more the liquid droplet volume in the destination drawing. A fine line pattern obtained by the fine line drawing method according to claim 1.