WO1999063588A1

WO1999063588A1 - Method for remelting solder layers

Info

Publication number: WO1999063588A1
Application number: PCT/EP1999/003800
Authority: WO
Inventors: Rolf Aschenbrenner; Joachim KLÖSER; Erik Jung; Luc Boone; Hubert De Steur; Marcel Heerman; Jozef Van Puymbroeck
Original assignee: Siemens S.A.
Priority date: 1998-06-02
Filing date: 1999-06-01
Publication date: 1999-12-09

Abstract

Solder layers (L) which are at least partially deposited on the conductor pattern of a wiring by electrodeposition, by chemical deposition or also by serigraphy must be remelted in order to improve their solderability. This remelting is selectively carried out with the assistance of a laser beam (LS3). In doing this, the wiring is subjected to only a minimal thermal stress.

Description

description

Process for remelting solder layers

The reliability of electronic devices depends to a large extent on the quality of the installed circuit boards. The quality of the printed circuit boards, in turn, is strongly dependent on the quality of the plated-through holes, their layer bonding and the soldering friendliness of the printed circuit board surface.

In order to facilitate the soldering work on printed circuits, their conductor tracks, which are made of copper, are often provided with a solder layer by galvanic deposition of tin or tin-lead, which is intended to prevent oxidation of the copper surfaces. This solder layer is then remelted by a heating process, for example by exposure to infrared radiation or by immersion in a hot oil bath (cf. DE-A-25 02 900). This remelting process is necessary because such electrodeposited solder layers cannot be soldered or can only be soldered poorly.

Due to the thermal load on the printed circuit boards when the galvanically applied solder layers are melted, mechanical stresses occur and the adhesion between resin and copper decreases. As a result of these phenomena, delamination of the printed circuit board and also tearing off of the plated-through holes can result. In order to avoid such damage to the printed circuit boards due to thermal stress, it was proposed in EP-A-0 330 922 to carry out the remelting of the electrodeposited solder layers in an overpressure container at elevated ambient gas pressure. The mechanical stresses that occur during remelting due to different coefficients of thermal expansion of the different materials are largely compensated for by the increased gas ambient pressure acting in all directions. The invention specified in claim 1 is based on the problem of creating a method for remelting solder layers which are at least partially applied to the conductor pattern of a wiring, and which can be carried out simply and quickly without harmful thermal stress on the wiring.

The invention is based on the finding that the remelting of solder layers applied to the conductor pattern of a wiring can be carried out selectively with the aid of a laser beam without heating the entire wiring. Since the solder layers can also be melted extremely quickly with the aid of a laser beam, the wiring is subjected to minimal thermal stress. Due to the locally limited remelting process which can be carried out within a time period of less than 0.1 seconds, the laser remelting can also be carried out in the case of wiring whose circuit carriers have only a low temperature resistance. Laser remelting can thus be used in all types of wiring, in particular also in flexible wiring, in injection molded parts produced using MID technology (MID = Molded Interconnection Devices) with integrated conductor tracks and in the polymer stud grid arrays known from WO-A-9609646, for example (PSGA) are applied. In addition to electrodeposited solder layers, laser remelting can also melt solder layers applied by chemical metal deposition or, for example, solder layers applied by screen printing.

Advantageous refinements of the method according to the invention for remelting solder layers applied to the conductor pattern of a wiring are specified in claims 2 to 6. The embodiment according to claim 2 enables a further reduction in the thermal load, since the remelting is carried out only at those points in the wiring where later good solderability must be ensured.

The embodiment according to claim 3 enables the formation of solder bumps on connection pads of a wiring by laser remelting. In this case, solder layers are melted on the connection pads and on conductor areas leading away from them and constricted in their width, the solder melted on these conductor areas flowing to the connection pads and the volume of the solder bumps that arise as a result of the melting on themselves being correspondingly increased. The width of the conductor areas serving as solder supply structures must be reduced in order to prevent the solder from flowing off over the subsequent conductor runs of the wiring. This eliminates the need to apply a solder resist to the corresponding areas of the wiring.

The development according to claim 4 enables a very rapid remelting of the solder layers with a particularly low thermal load on the circuit carriers.

According to claim 5, Nd: YAG lasers with a wavelength of 1.06 μm have proven particularly good for remelting solder layers. The laser remelting of solder layers can in principle also be carried out with a diode laser array or with a strip-shaped laser beam. According to claim 6, however, laser remelting with the aid of a deflectable laser beam is preferred, since this results in a very high degree of flexibility and also enables a targeted selection of the areas to be melted. In addition, the areas of a solder layer to be melted can be scanned extremely quickly with a deflectable laser beam. An embodiment of the invention is shown in the drawing and will be described in more detail below.

Figures 1 to 6 show different stages of the process in the production of wiring and the formation of solder bumps on the connection pads of this wiring.

FIG. 7 shows the finished wiring after a semiconductor component has been soldered on.

FIG. 1 shows an electrically insulating substrate S with a metallization M applied on one side. This metallization M is a thin copper lamination or a layer applied by chemical metal deposition of copper. The metallization M is then structured with an Nd-YAG laser with a wavelength of 1.06 μm, this laser structuring being indicated in FIG. 1 by a laser beam LSI.

According to FIG. 2, connection pads P and conductor lines, LZ are produced in the laser structuring, the connection pads P being connected to the further conductor lines via conductor regions LB of reduced width. The wiring also has a collecting line SL, which is connected to the individual connection pads P via solder supply structures LS, which are also reduced in width compared to the conductor tracks LZ. The SL collecting line enables cathodic contacting of the entire conductor pattern and thus galvanic metal deposition on the conductor pattern.

According to FIG. 3, a reinforcing layer V made of copper and a solder layer L made of a tin-lead alloy are applied in succession to the conductor pattern by galvanic metal deposition. The electrical separation of the collecting line SL from the rest of the conductor pattern is initiated by a laser beam indicated in FIG. 3 by an arrow LS2. in this connection

REPLACEMENT SHEET (RE3EL8Θ) the Nd-YAG laser with a wavelength of 0.355 μ or 1.06 μm is used to remove the solder layer L in the areas of the solder feed structures LS directly adjacent to the collecting line SL, whereupon the copper of the reinforcing layer V and the metallization M thereby exposed, as shown in FIG. 4 is removed by etching up to the surface of the substrate S.

FIG. 4 also shows a deflectable laser beam LS3, with which the solder layer L is melted simultaneously on a connection pad P, on the conductor area LB leading away therefrom and on the solder supply structure LS leading away therefrom. For this purpose, an Nd-YAG laser with a wavelength of 1.06 μm is used, the laser beam LS3 of which is strongly out of focus.

In the case of the laser remelting of the solder layer L as described, the liquid solder flows from the narrow solder supply structure LS and from the narrow conductor region LB to the connection pad P, so that a solder bump LH is automatically created there according to FIG. The volume of the solder bump LH can optionally be further increased by additional, narrow solder feed structures leading away from the connection pad P and ending blindly.

FIG. 6 shows the arrangement of a bumpless semiconductor component HB on the wiring, the connection surfaces AF of which, for example, consist of a layer sequence of aluminum, nickel and gold, lie directly on the tips of the associated solder bumps LH. If all the solder bumps LH assigned to the semiconductor module HB are subsequently melted simultaneously, for example by reflow soldering or by laser soldering, reliable soldered connections with the concave shape of the solder bumps LH shown in FIG. 7 result.

With ordinary conductor patterns without width-reduced conductor areas LB and without width-reduced solder

SPARE BLADE (RULE 26) driving structures LS, the described laser remelting of solder layers L can of course also be carried out. Here then there are only flat solder dots instead of the high solder bumps LH on the connection pads.

Claims

claims

1. A method for remelting solder layers (L) which are at least partially applied to the wiring pattern of a wiring, by means of the fact that the solder layers (L) are selectively melted using a laser beam (LS3).

2. The method according to claim 1, characterized in that the solder layers (L) are selectively melted in the area of connection pads (P) of the wiring.

3. The method according to claim 1, characterized in that the solder layers (L) to form solder bumps (LH) on connection pads (P) of the wiring selectively in the area of the connection pads (P) and leading away, in the width - Laced conductor areas (LB, LS) are melted.

4. The method according to any one of the preceding claims, characterized in that the solder layers (L) are melted with the aid of a laser beam (LS3) which is strongly out of focus.

5. The method according to any one of the preceding claims, characterized in that the solder layers (L) are melted with the laser beam (LS3) of a Nd.YAG laser with a wavelength of 1.06 μm.

6. The method according to any one of the preceding claims, characterized in that the solder layers (L) are melted using a deflectable laser beam (LS3).