Conducting package structure and manufacturing method thereof

Abstract

A conducting package structure includes a substrate and a conducting material. The conducting material is formed to a first patterned structure. The first patterned structure has a first surface which is connected to the substrate and a patterned second surface opposite to the first surface.

Claims

1. A conducting package structure, comprising: a substrate; and a conducting structure having a first surface disposed on the substrate and a second surface formed with a plurality of guide rods, a first auxiliary structure including a plurality of cylinders and a plurality of triangular pyramids and a second auxiliary structure including a plurality of concentrically circular pieces, wherein any two adjacent guide rods have therebetween a distance larger than two times of a width of either of the any two adjacent guide rods, and the first auxiliary structure is configured to accelerate a volatilization of a solvent of a glue material disposed on the second surface.

2. The conducting package structure as claimed in claim 1, wherein the substrate is one of a ceramic substrate and a printed circuit board.

3. The conducting package structure as claimed in claim 1, wherein the second auxiliary structure is configured to retard a diffusion of a solvent of the glue material.

4. The conducting package structure as claimed in claim 3, wherein the second auxiliary structure is further configured to retard an overflow of the solvent.

5. A conducting package structure, comprising: a substrate; and a conducting material formed with a first patterned structure, wherein the first patterned structure has a first surface disposed on the substrate and a second surface opposite to the first surface, the second surface is formed with a first auxiliary structure including a plurality of cylinders and a plurality of triangular pyramids and configured to accelerate a volatilization of a solvent of a glue material disposed on the second surface, and a second auxiliary structure configured to retard a diffusion of the solvent of the glue material.

6. The conducting package structure as claimed in claim 5, wherein the second auxiliary structure includes a plurality of concentrically circular pieces.

7. The conducting package structure as claimed in claim 5, wherein two adjacent rows of the cylinders are disposed between respective adjacent two of the plurality of triangular pyramids.

8. The conducting package structure as claimed in claim 5, wherein the substrate is one of a ceramic substrate and a printed circuit board.

9. The conducting package structure as claimed in claim 5, wherein the second auxiliary structure is further configured to retard an overflow of the solvent.

10. A conducting package structure, comprising: a substrate; and a conducting structure having a first surface disposed on the substrate and a second surface formed with a first auxiliary structure including a plurality of cylinders and a plurality of triangular pyramids, wherein two adjacent rows of the cylinders are disposed between respective adjacent two of the plurality of triangular pyramids, and the first auxiliary structure is configured to accelerate a volatilization of a solvent of a glue material disposed on the second surface.

11. The conducting package structure as claimed in claim 10, wherein the second surface is further formed with a second auxiliary structure including a plurality of concentrically circular pieces.

12. The conducting package structure as claimed in claim 11, wherein the second auxiliary structure is configured to retard a diffusion of a solvent of the glue material.

13. The conducting package structure as claimed in claim 12, wherein the second auxiliary structure is further configured to retard an overflow of the solvent.

14. The conducting package structure as claimed in claim 10, wherein the substrate is one of a ceramic substrate and a printed circuit board.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIGS. 1A-1C show diagrams of a conducting package structure according to a preferred embodiment of the present invention processed;

(2) FIG. 2A shows a top view of a conducting structure with a patterned surface according to a preferred embodiment of the present invention processed;

(3) FIG. 2B shows a side view of a glue material and a relationship of a solvent of the glue material and a conducting structure;

(4) FIG. 2C shows another side view of a glue material and a relationship of a solvent of the glue material and a conducting structure;

(5) FIGS. 2D-2F show top views of conducting structures with different patterned surfaces according to a preferred embodiment of the present invention; and

(6) FIG. 3 is a side view of the conducting package structure according to a preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

(7) The present invention will now be described more specifically with reference to the following embodiments. It is to be noted that the following descriptions of preferred embodiments of this invention are presented herein for the purposes of illustration and description only; they are not intended to be exhaustive or to be limited to the precise form disclosed.

(8) The present invention can be applied in the electronic packaging industry. The present invention utilizes the principles of the Wenzel model to design a conducting structure conforming to the Wenzel model, wherein the applied Wenzel model relates to the relationship between the surface tension of a droplet (that is, a colloid in the present invention) and the roughness of a substrate, wherein the roughness of the substrate can be achieved by employing patterning treatment on a surface of the substrate, wherein a specific surface area of the surface with the patterning treatment is increased, meaning that the roughness of the substrate is increased. The Wenzel model is the evolved version of the Young equation. The Young equation refers to the relationship of a contact angle of a liquid on a surface solid where three interfacial tensions balance. The Young equation is as shown in equation (1):
γ.sub.sg=γ.sub.sl+γ.sub.gl×cos θ  (1)

(9) γ.sub.sg denotes solid-vapor interfacial tension; γ.sub.sl denotes solid-liquid interfacial tension; γ.sub.gl denotes vapor-liquid interfacial tension and θ denotes the angle at which the vapor-liquid interface meets the solid-liquid interface and is also called the contact angle. The contact angle is defined as the angle formed by the intersection of the vapor, liquid and solid phases contact point (geometrically acquired by applying a tangent along the vapor-liquid interface at the contact point between liquid and solid). In the present invention, the contact angle is also called the wetting angle, and is used to quantify the wettability. If θ<90°, the surface of the solid phase is hydrophilic, the liquid phase has higher wettability on the surface of the solid phase. On the contrary, if θ>90°, the surface of the solid phase is hydrophobic, the liquid phase has lower wettability on the surface of the solid phase and is liable to move on the surface of the solid phase.

(10) If a droplet is dropped on a rough solid surface, under the influence of the roughness, the Young equation will cause errors, and therefore, research with regard to the influence caused by roughness on the contact angle, such as the Wenzel model and the Cassie model, wherein the Wenzel model is shown as in equation (2).
cos θ=r(γ.sub.sg−γγ.sub.sl)/γ.sub.gl=r cos θ.sub.c  (2)

(11) θ denotes a contact angle formed by the intersection at the contact point of the liquid on a smooth surface of a solid body. θ.sub.c denotes another contact angle formed by the intersection at the contact point of the liquid on a rough surface of a solid body. γ.sub.sg denotes solid-vapor interfacial tension. γ.sub.sl denotes solid-liquid interfacial tension. γ.sub.gl denotes vapor-liquid interfacial tension. r denotes the roughness of the surface of the solid and is a ratio of actual contact area to apparent contact area, r≧1. When the surface of the solid body is hydrophobic, cos θ.sub.c<0 and 90°<θ.sub.c<180°, then cos θ<cos θ.sub.c and θ>θ.sub.c. When the surface of the solid body is hydrophilic, cos θ.sub.c>0 and 0°<θ.sub.c<90°, then cos θ>cos θ.sub.c and θ<θ.sub.c.

(12) Furthermore, the present invention also refers to research with regard to a relationship between a liquid (such as a volatile chemical solvent, called solvent hereinafter) and body surface area dimension of surface of a solid body. When the solvent is disposed on the surface of the solid body, the solvent will be influenced by the structure of the solid body surface. For example, if the structure of the solid body surface has a plurality of triangular pyramids, it will guide the solvent in a specific diffusing direction and increase the diffusion rate of the solvent; if the structure of the solid body surface has a plurality of cylinders or pillars of any other shape, compared to the structure of the solid body only having a planar surface, it will have larger total body surface area causing the diffusible area of the solvent to increase, also increasing the rate of volatilization of the solvent. Therefore, it can be seen that the total body surface area of the solid body surface is in direct proportion to the rate of volatilization of the solvent.

(13) As described above, we conclude that by changing the roughness of the solid body surface, we can determine the contact angle of the liquid on the solid body surface and thereby change the wettability of the solid body surface. The present invention utilizes this principle for SMT technology for electronic packaging, the dispensing technique and the dot control technique to cause an adhesive material used for pasting to have a surface tension when it is placed on the surface of the post-patterning treatment substrate, and further to cause the adhesive material to have a wetting angle on the substrate and appear as a semicircular shape. In addition, according to the fact that the surface of the substrate is characterized by a roughness (conforming to the Wenzel model) after the patterning treatment, there is an interfacial tension generated between the adhesive material and the surface of the substrate, confining the adhesive material to a certain position. Furthermore, the present invention further utilizes another roughness (simply increases the total specific surface area of the solid body surface) to accelerate the volatilization of the solvent of the adhesive material and control the diffusion degree of the solvent. Therefore, the shape and position of an adhesive material used for pasting presented in the present invention are consistent with the shape and position of the surface of the post-patterning treatment substrate, further to cause the electronic device to past with no deviation, thus achieving high stability and product capacity with a high yield factor.

(14) The concepts of the present invention are illustrated below.

(15) Please refer to FIGS. 1A, 1B and 1C, which respectively show diagrams of a conducting package structure according to a preferred embodiment of the present invention processed during a first state, a second state, and a third state. As shown in FIG. 1C, the conducting package structure processed during the third state includes a substrate 11, at least a conducting structure 12 (and optional conducting structures 13, 14, and 15), at least a glue material 18 (and an optional glue material 19), and an electronic device 20, wherein each conducting structure includes a conducting pad.

(16) The process of the conducting package structure according to the present invention is mainly divided into Step 1 and Step 2. As shown in FIG. 1A, Step 1 performs a pretreatment on the substrate. As shown in FIGS. 1B and 1C, Step 2 binds the electronic device 20 to the substrate 11. With regard to Step 1, FIG. 1A shows a conducting material (such as: copper, gold, silver, or any other conductor) first being deposited or coated on the substrate 11 and etched to form the conducting structures 12, 13, 14 and 15. As shown in FIG. 1B, the conducting structures 12, 13, 14 and 15 separately have a plurality of patterned surfaces (not shown), wherein the plurality of patterned surfaces is formed according to the Wenzel model and increases the total specific surface area of the surface. That is, a primary structure of the plurality of patterned surfaces conforms to the Wenzel model and a secondary structure thereof is a surface structure having a relatively increased specific surface area. The details of the patterned surface will be described in detail below. As shown in FIG. 1B, in Step 2, the glue materials (or colloids) 18 and 19 are respectively dispensed on the conducting structure 12 and the conducting structure 13, 14 or 15. For example, the conducting structures 14 and 15 may be dispensed with two glue materials (not shown) thereon for fixing the electronic device 20. As shown in FIG. 1C, the conducting structures (also referred to as the conducting pad) 12 and 13 respectively limit a formed shape and a formed position of the glue materials 18 and 19. Under the condition that the glue materials 18 and 19 have a specific shape and a specific position, the electronic device 20 is disposed on the glue materials 18 and 19 to complete a conducting package structure 10.

(17) In one preferred embodiment, the substrate 11 includes a ceramic substrate, a printed circuit board or any other form of electronic substrate. The conducting structures 12 and 13 separately have two patterned surfaces, and the two patterned surfaces may be for limiting the shape and position of the glue materials 18 and 19 respectively. The conducting structures 12 and 13 separately include two or more patterned surfaces (as shown in FIGS. 2A-2F), wherein the patterned surfaces are formed using a photolithography process, a dry-film photo-resister process, a screen printing process or any other film formation process. All of the glue materials 18 and 19 include a polymer, an organic material, a catalyst, a binding agent or a combination thereof. The electronic device 20 includes an integrated circuit, a capacitance, a transistor, a resistance or a quartz.

(18) In one preferred embodiment, the substrate 11 at least includes a conducting structure (e.g., the conducting structure 12). For example, the conducting structures 12, 13, 14 and 15 are symmetrically disposed on the substrate 11.

(19) In one preferred embodiment, as shown in FIG. 1C, the substrate 11 includes the conducting structures 12, 13, 14 and 15. The conducting structure 12 and the conducting structure 13 have therebetween a first distance 16, the conducting structure 13 and the conducting structure 15 have therebetween a second distance 17, and the second distance 17 is larger than the first distance 16. The conducting structures 12 and 15 are disposed on the diagonal corners of the substrate 11, so as to stably connect with the electronic device 20 because of the corresponding glue materials 18 and 19.

(20) Please refer to FIG. 2A, which shows a top view of a conducting structure 200 with a patterned surface 2A. In one preferred embodiment, a conducting structure 200 includes a conducting pad 205 (e.g., copper, gold, silver, or any other conductor), a plurality of guide rods 201, and a first auxiliary structure and a second auxiliary structure 204. Wherein, the first auxiliary structure includes a plurality of cylinders 202 and a plurality of triangular pyramids 203, and the second auxiliary structure 204 is a plurality of concentrically circular pieces 204. Wherein, the plurality of guide rods 201 is designed to conform to the Wenzel model, and the plurality of cylinders 202 and the plurality of triangular pyramids 203 conform to a principle of increasing a total specific surface area of a surface structure of the conducting pad 205. Therefore, the conducting structure 200 limits a dot (not shown) of a glue material by the plurality of guide rods 201, accelerates a volatilization of a solvent of the glue material and the diffusing direction of the solvent (not shown) by the plurality of cylinders 202 and the plurality of triangular pyramids 203, and controls the diffusing degree of the solvent by the plurality of concentrically circular pieces 204, i.e., the plurality of concentrically circular pieces 204 is used to retard an overflow of the solvent.

(21) Please refer to FIG. 2B, which shows a side view of a glue material (or a colloid) 22 and a relationship of a solvent 221 of the colloid 22 and a conducting structure 21 with a patterned surface 2A. In one preferred embodiment, the patterned surface 2A is formed with a plurality of guide rods 211 and a plurality of cylinders 215. The conducting structure 21 is disposed on a substrate 206 and limits a dot of a glue material 22 by the plurality of guide rods 211, i.e., the plurality of guide rods 211 of the conducting structure 21 generate an enhanced mutual interfacial tension on the dispensed glue material 22 to limit the glue material 22 to a certain region. Furthermore, the total specific surface area of the conducting structure 21 is increased by the plurality of cylinders 215. The solvent 221 diffused from the colloid 22 and the surface of the plurality of cylinders 215 form a gas-solid interface and so a vaporization phenomenon 222 appears on the surface of the plurality of cylinders 215. Because the plurality of cylinders 215 are dense arrays to increase a diffusible specific surface area of the solvent 221, the vaporizing rate of the solvent 221 is accelerated. Wherein, any two adjacent guide rods 211 of the plurality of guide rods 211 have therebetween a first distance 231, each guide rod 211 has a second distance 232 of width and a third distance 233 of height, and a first proportional relationship of the first distance 231 and the second distance 232 conforms to the Wenzel model, as shown in FIG. 2D.

(22) Please refer to FIG. 2C, which shows another side view of a glue material (or colloid) 22 and a relationship of a solvent 221 of the colloid 22 and a conducting structure 21 with a patterned surface 2A. In one preferred embodiment, the patterned surface 2A is formed with a plurality of guide rods 211 and a plurality of triangular pyramids 219. The conducting structure 21 is disposed on a substrate 206, and limits a dot of the colloid 22 by the plurality of guide rods 211, i.e., the plurality of guide rods 211 of the conducting structure 21 generate an enhanced mutual interfacial tension on the dispensed colloid 22 to limit the glue material 22 to a certain region. Moreover, the diffusing direction of the solvent 221 diffused from the colloid 22 is guided outward by the structure of the plurality of triangular pyramids 219. At the same time, a vaporization phenomenon 222 appears on a structure surface of the plurality of triangular pyramids 219 and so the vaporizing rate of the solvent 221 is accelerated. Wherein, any two adjacent guide rods 211 of the plurality of guide rods 211 have therebetween a first distance 231, each guide rod 211 has a second distance 232 of width and a third distance 233 of height, a first proportional relationship of the first distance 231 and the second distance 232 conforms to the Wenzel model, as shown in FIG. 2D.

(23) In one preferred embodiment, as shown in FIGS. 2B and 2C, the plurality of guide rods 211, designed under the conditions that conform to the Wenzel model, can achieve the objective of the present invention. The conditions include a preset dimension relationship of A>2D (preferably A>>2D), wherein the distance 231 between any two adjacent guide rods is A, the width 232 of any of the two adjacent guide rods is D (the above-mentioned embodiments do not illustrate an effect of the height and only consider the effects of the A value and D value.)

(24) In one preferred embodiment, as shown in FIGS. 2B and 2C, the plurality of cylinders 215, designed under the condition of increasing the specific surface area and guiding the direction of the solvent 221, can achieve the objective of the present invention. The condition includes dense arrays in any way on a surface structure in any form.

(25) Please refer to FIGS. 2D-2F, which respectively show top views of the conducting structures 23, 28 and 33 with different patterned surfaces according to a preferred embodiment of the present invention. In one preferred embodiment, the conducting structures 23, 28 and 33 include a plurality of guide rods 24, 25, 26, 29, 30, 31, 34, 35 and 36, which have shapes in plan view of a circle 27, a square 32, a rectangle 37, an ellipse, any shape conforming to a proportional relationship or a combination thereof. The plurality of guide rods 24, 25, 26, 29, 30, 31, 34, 35 and 36 further include a plurality of dense cylinder arrays, a plurality of dense acicular arrays or a plurality of multi-layer dense cylinder arrays, or any structure conforming to this condition.

(26) In one preferred embodiment, as shown in FIG. 2D, the first auxiliary structures 215 and 216, designed under a condition of increasing the specific surface area and being capable of direction guidance, can achieve the objective of the present invention. The condition includes dense arrays in any design on a surface structure in any form. For example, the first auxiliary structure further includes a cube, a cuboid, a cone, and any shape capable of increasing the specific surface area, and the dense arrays in any way further include a plurality of dense cylinder arrays, a plurality of dense acicular arrays or a plurality of multi-layer dense cylinder arrays; wherein the second auxiliary structure 217 determines the diffusing degree of the solvent.

(27) In another preferred embodiment, the plurality of guide rods 24, 25, 26, 29, 30, 31, 34, 35 and 36 have a first total specific surface area, and the plurality of pillars 215 and 216 formed on the first auxiliary structure have a second total specific surface area, wherein the second total specific surface area is larger than the first total specific surface area.

(28) Please refer to FIG. 3, which is a side view of the conducting package structure according to a preferred embodiment of the present invention. The conducting package structure 300 includes a substrate 310, a conducting structure 320, a plurality of guide rods 321, a glue material 330 and an electronic device 340.

(29) In one preferred embodiment, a method for manufacturing conducting package structure 300 includes the following steps. First, a conducting material (e.g., copper, gold, silver, or any other conductor) is deposited or coated on the substrate 310 and etched to form a conducting structure 320 with a patterned surface, wherein the conducting structure 320 includes a spatial structure and a patterned surface. Then, a glue material 330 is dispensed on the conducting structure 320 using a dispensing method, wherein a formed shape and a formed position of the glue material 330 are limited by the conducting structure 320 with the patterned surface, and a wetting angle 350 is between the glue material 330 and the conducting structure 320. Then, the electronic device 340 is disposed on the glue material 330 to complete a conducting package structure 300. For example, the patterned surface is formed with a plurality of guide rods 321.

(30) In one preferred embodiment, the conducting structure 320 disposed on the substrate 310 conforms to the Wenzel model, and the conducting structure 320 has the patterned surface, which increases the roughness of the substrate 310. According to a reciprocal effect between a roughness of a surface and a droplet, as expressed by equation (2), it can be seen that the glue material 330 is dispensed on the substrate 310 with a rough surface, an interfacial tension is therebetween generated, and so the glue material 330 has a surface tension to fix the shape and position of the glue material 330.

(31) In one preferred embodiment, the conducting structure 320 includes a spatial structure and has a patterned surface, wherein the patterned surface is formed with a plurality of cylinders 215, the plurality of cylinders 215 conforms to the feature of increasing the total specific surface area of the patterned surface. According to the design feature, it can be seen that when the solvent diffuses into the plurality of cylinders 215, an interfacial tension is therebetween generated and so the solvent has a surface tension to cause a vaporization phenomenon 222 on the surface of the plurality of cylinders 215, so as to diffuse the solvent in nebulized gas 223 into the environment.

(32) In one preferred embodiment, the glue material 330 has a wetting angle 350 (contact angle θ) with the substrate due to the patterned surface, and the wetting angle 350 ranges from 15 to 85 degrees.

(33) In one preferred embodiment, the glue material 330 on the substrate 310 has a surface tension, so as to shape the glue material 330 on the substrate 310 into a semicircle, wherein the glue material 330 has an acme for connecting with the electronic device 340.

(34) In one preferred embodiment, the wetting angle 350 is determined by the patterned surface of the conducting structure 320 on the substrate 310. When the patterned surface has a preset dimensional relationship where any two adjacent guide rods have therebetween a distance larger than two times the width 370 of any of the two adjacent guide rods, the position and yield of the connected electronic device 340 are further controlled. In one preferred embodiment, the substrate 310 includes a ceramic substrate, a printed circuit board, or any other form of electronic substrate.

(35) In one preferred embodiment, the conducting structure 320 includes a first surface 323 and a second surface 322 opposite to the first surface 323. The second surface 322 is formed with a plurality of guide rods 321. The conducting structure 320 may be for limiting the shape and position of the glue material 330.

(36) In one preferred embodiment, the conducting structure 320 includes a first surface 323 and a second surface 322 opposite to the first surface 323. The second surface 322 is formed with a plurality of guide rods 321, a plurality of cylinders 202, a plurality of triangular pyramids 203 and a plurality of concentrically circular pieces 204 (as shown in FIG. 2A). One of the plurality of cylinders 202, the plurality of triangular pyramids 203 and the plurality of concentrically circular pieces 204 is made of a material selected from a conductor, e.g., copper, and a non-conductor, e.g., a polymer material.

(37) In one preferred embodiment, the conducting structure 320 includes at least a conducting pad, wherein the conducting pad is formed using a photolithography process, a dry-film photo-resister process, a screen printing process or a film formation process.

(38) In one preferred embodiment, the glue material 330 includes a polymer, an organic material, a catalyst, a binding agent or a combination thereof.

(39) In one preferred embodiment, the dispensing method is a time-pressure dispensing method, a rotary dispensing method or a pump dispensing method.

(40) In one preferred embodiment, the glue material 330 has enhanced interfacial tension on the conducting structure 320 of the substrate for fixing the position of the glue material 330. Moreover, because the conducting structure 320 causes the glue material 330 to have a surface tension, the surface tension holds the glue material in a semicircle, not any other shape.

(41) In one preferred embodiment, the electronic device 340 includes an integrated circuit, a capacitance, a transistor, a resistance or a quartz.

(42) The present invention discusses the relationship of the conducting structure (conducting pad) and the glue material, wherein, the primary structure conforms to the Wenzel model; and a secondary structure is a treatment for a conducting structure (conducting pad) on the substrate according to an effect principle of a specific surface area of a solid surface and a liquid disposed thereon. Therefore, the surface of the conducting structure has a structure capable of controlling the position and shape of the glue material to further solve the problems of a component (i.e., the electronic device) in adhering accuracy and available yield. However, the aforementioned patent discussed that the asymmetrical and lateral surface-tension forces between devices and a substrate are reduced by at least a conducting pad on the patterned substrate. Accordingly, it can be seen that the aforementioned patent researched into reducing the size of the conducting pad (i.e., reducing a distance along X direction) reduces the force of the X direction and so the resultant force of the X-Y directions is reduced to stabilize the connection of the electronic device and the substrate. Thus, the aforementioned patent discussed the relationship of a varying conducting pad and the electronic device, which is different from the relationship of the glue material and the conducting structure (conducting pad) with a patterned surface. One skilled in the art could not derive the techniques and the results of the present invention from the aforementioned patent.

EMBODIMENTS

(43) 1. A method for manufacturing a conducting package comprising: providing a substrate; forming a conducting structure on the substrate, wherein the conducting structure has a surface; patterning the surface to form a patterned surface; dispensing a glue material on the patterned surface, wherein a wetting angle between the glue material and the patterned surface is determined by the patterned surface; and disposing an electronic device on the glue material.

(44) 2. A method of Embodiment 1, wherein the conducting structure comprises at least a conducting pad formed by one selected from a group consisting of a photolithography process, a dry-film photo-resister process and a screen printing process.

(45) 3. A method of Embodiments 1-2, wherein the glue material is dispensed by one selected from a group consisting of a time-pressure dispensing method, a rotary dispensing method and a pump dispensing method.

(46) 4. A method of Embodiments 1-3, wherein the wetting angle ranges from 15 to 85 degrees.

(47) 5. A method of Embodiments 1-4, wherein the patterned surface conforms to the Wenzel model.

(48) 6. A method of Embodiments 1-5 further comprises: providing a first auxiliary structure and a second auxiliary structure in the conducting structure, wherein: the first auxiliary structure includes a plurality of cylinders and a plurality of triangular pyramids to determine the volatility and the diffusing direction of a solvent thereon; and the second auxiliary structure includes a plurality of concentrically circular pieces to determine the diffusing degree of the solvent.

(49) 7. A conducting package structure comprising: a substrate, a conducting structure and a glue material, wherein: the conducting structure is formed on the substrate, and has a patterned surface; and the glue material is disposed on the patterned surface, wherein a wetting angle between the glue material and the patterned surface is determined by the patterned surface.

(50) 8. The conducting package structure of Embodiment 7, wherein the conducting structure includes at least a conducting pad.

(51) 9. The conducting package structure of Embodiments 7-8, wherein the conducting structure further includes: a first auxiliary structure configured to accelerate the volatilization of a solvent of the glue material; and a second auxiliary structure configured to retard the diffusion of the solvent.

(52) 10. The conducting package structure of Embodiments 7-9, wherein the first auxiliary structure includes a plurality of cylinders and a plurality of triangular pyramids.

(53) 11. The conducting package structure of Embodiments 7-10, wherein the second auxiliary structure includes a plurality of concentrically circular pieces.

(54) 12. The conducting package structure of Embodiments 7-11, wherein the wetting angle is an included angle between of the patterned surface and a tangent at a contact point between the glue material and the patterned surface, and the wetting angle ranges from 15 to 85 degrees.

(55) 13. The conducting package structure of Embodiments 7-12, wherein the substrate is one of a ceramic substrate and a printed circuit board and one of the first auxiliary structure and the second auxiliary structure is made of a material selected from one of a conductor and a non-conductor.

(56) 14. The conducting package structure of Embodiments 7-13, wherein the glue material includes one selected from a group consisting of a polymer, an organic material, a catalyst, a binding agent, and a combination thereof.

(57) 15. The conducting package structure of Embodiments 7-14, wherein the conducting structure comprises a plurality of cylinder arrays, a plurality of acicular arrays and a plurality of multi-layer cylinder arrays.

(58) 16. The conducting package structure of Embodiments 7-15, wherein an electronic device being one selected from a group consisting of an integrated circuit, a capacitance, a transistor, a resistance and a quartz is disposed on the glue material.

(59) 17. A conducting package structure comprising: a substrate; and a conducting structure having a first surface disposed on the substrate and a second surface formed with a plurality of guide rods, wherein any two adjacent guide rods have therebetween a distance larger than two times of a width of any of the two adjacent guide rods.

(60) 18. The conducting package structure of Embodiment 17, wherein the plurality of guide rods includes a structure being one selected from a group consisting of a plurality of cylinder arrays, a plurality of acicular arrays and a plurality of multi-layer cylinder arrays; the plurality of guide rods have a first total specific surface area; and the second surface is further formed with a plurality of pillars, and the plurality of pillars have a second total specific surface area, wherein the second total specific surface area is larger than the first total specific surface area.

(61) 19. A conducting package structure comprising: a substrate; and a conducting material formed with a first patterned structure, wherein the first patterned structure has a first surface disposed on the substrate and a second surface opposite to the first surface.

(62) 20. The conducting package structure of Embodiment 19, wherein the second surface includes a primary structure and a secondary structure, the primary structure conforms to the Wenzel model, and the secondary structure has a relatively increased specific surface area on the second surface.

(63) In conclusion, the present invention utilizes a surface micro-processing for the surface to cause the surface of the substrate conform to the Wenzel model, so as to control the range of the contact angle between the semi-fluid glue material and electronic device. Thereby the relative positions among the substrate, the glue material and the packaged electronic device are fixed. The substrate with the surface micro-processing has a specific surface area to cause the organic solvent to diffuse and evaporate quickly. Thereby, the liquidity of the glue material after it is dispensed on the substrate is quickly reduced and the dot size of the glue material is shrunk. Thus, the present invention has the advantages of quickly and accurately assembling electronic devices and eliminating or decreasing the prebaking time.

(64) While the invention has been described in terms of what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention needs not be limited to the disclosed embodiments. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures.