The invention relates to a method for the production of vertical through-plated holes (micro-vias, pocket hole vias or “blind” vias, via=vertical interconnect access) in semiconductor wafers for the fabrication of semiconductor devices, i.e., of contacts extending from the front side of the wafer, through the semiconductor wafer to the rear side of the wafer.
The properties (for example, high-frequency properties) of the devices can be fully utilized only by an increasingly more compact integration into the periphery. Short vertical connections represent an efficient way of electrical contacting. In addition, it is necessary for physical reasons—in order to enhance the amplification and the maximum output power of the high-frequency transistors available per chip—to establish a low-inductance electrically conductive connection between the source contacts on the front side and the ground electrode on the rear side. This, however, cannot always be easily implemented considering the technology.
Electrically active GaN (gallium nitride) material is currently virtually not available as a mono-crystalline wafer material and is thus epitactically grown on substrate materials such as, for example, SiC wafers (silicon carbide).
SiC is noted for its very good thermal conductivity, as well as its extremely high chemical stability and great hardness. Therefore, it is necessary for contacting the rear side of the GaN transistors to drill through the carrier material of SiC, as well as through the superimposed epitactical GaN layer. For texturing, until now only dry-chemical etching processes such as reactive ion etching could be used in practice in high-performance plasma etching reactors that are specifically optimized for this purpose. However, at 1 μm/min, typical plasma etching rates of SiC are very low. In addition, the use of plasma etching technology requires the production and lithographic texturing of a durable etching mask.
It has been known that printed circuit boards can be provided with vias by using lasers. Referring to these technologies, openings can be drilled into the copper layers and dielectric layers, and these can then be metallized in order to create electrical connections between certain layers. Different laser technologies use lasers such as CO2 lasers, frequency-doubled (green) YAG lasers, excimer lasers and UV:YAG lasers.
The production of these vias has been described in the following, for example:
At the present time, there is no known laser technology-based method that is known for the production of micro-vias in semiconductor wafers.
The object of the invention is to provide an effective method for the production of micro-vias in semiconductor wafers of materials displaying great hardness and stability, such as silicon carbide, sapphire or the like.
In accordance with the invention, this object is achieved by a method displaying the features of claim 1. Practical embodiments are the subject matter of the subclaims.
In accordance with these, the method is characterized by the following steps:
In order to protect the wafer during the process, a protective varnish may be applied to the front side of the wafer as a protective measure, said protective varnish being removed again after the process (varnish removal).
In order to avoid a thinning of the semiconductor substrate during the etching process, the rear side of the wafer may be coated with indium tin oxide (ITO) before laser-drilling the pocket bores, said ITO being simply removed again after plasma etching.
In the case of SiC substrate material, cleaning of the wafer to remove debris is practically achieved with buffered hydrofluoric acid.
As the material-selective etching process for the semiconductor substrate, the ICP etching process (inductively coupled plasma) is particularly preferred; for the layer stack, it is the RIE process (reactive ion etching).
As the laser, a UV laser is suitable, preferably a frequency-tripled Nd:YAG laser with a wavelength of 355 nm.
The application of the plating base in the micro-vias may occur with several methods. Preferred is an oblique vapor deposition; also possible are a chemical bath deposition (current-less) or an application by sputtering.
If needed, the gold layer may additionally be coated with a dewetting layer at the locations of the micro-vias. Suitably, titanium is used for the dewetting layer, whereby the titanium may be deposited by sputtering. The dewetting layer is effectively coated with the use of a shadow mask.
The method has the advantage in that micro-vias can be produced in hard and chemically inert substrate materials within a substantially reduced time and with high precision.
In accordance with the method of the present invention, micro-machining of material by means of UV laser radiation is combined with plasma etching and used for direct texturizing in the fabrication of components. In contrast with the production of through-wafer vias (or hollow-rivet vias), there is no full perforation of the material. The residual material is removed by plasma etching up to the contacts of the front side in a material-selective manner. The particular advantage of this is that a resistant etching mask need not be lithographically produced, but that the laser-drilled holes act as the etching mask. If the side that is being machined is protected in a suitable manner, the material density is maintained. In this case, a protective layer that is being perforated by the laser prevents the planar material removal during plasma etching. If no protective layer is used, the removal of material by etching over large areas takes place. The concurrent reduction of the material thickness may be estimated in view of known etching rates.
Hereinafter, the invention will be explained in detail with reference to an exemplary embodiment. Related schematic drawings show the phases of the inventive method, for example, the production of micro-vias in silicon carbide (SiC) for GaN high-performance field effect transistors or MMICs.
They show in:
Following is a description of the process control of the method in accordance with the invention and of the achieved results.
Loose particles (debris) that may have deposed on the sample during the drilling operation are subsequently removed by a cleaning step using wet chemistry. This is suitably done by etching in buffered hydrofluoric acid with ultrasound.
The pocket holes 11 that have been pre-drilled by the laser are subsequently etched through to the front-side contacts by plasma etching with the use of dry chemicals (
The removal of the epitactical layer having a thickness of 2-3 μm (layer stack 2) is accomplished by plasma-chemical means with an RIE process, for example, with boron trichloride/chlorine (BCl3/Cl2). The selectivity of the dry chemical etching process of GaN versus platinum is >10:1. The metal layer of the front-side contact having a total thickness of approximately 5 μm is now stripped only very gradually, i.e., in practice, the etching process stops at the metal layer. Underetching does not occur. A titanium layer located under the platinum contacts and having a thickness of a few 10 nm is stripped.
Following the etching process, the potentially applied layer 10 (ITO) may be removed again, this being effectively done with iron-III-chloride (
Subsequently, a thin metal layer 12 is vapor-deposited on the rear side of the wafer. In doing so, referring to this exemplary embodiment, a cohesive coverage of the hole walls is achieved by oblique vapor deposition. Also possible are other metallizing processes such as sputtering or currentless chemical deposition. The plating base obtained with the metal layer 12 is subsequently reinforced by applying an electroplated gold layer 13 that typically has a thickness of 5 μm (
Following metallization, the protective varnish is stripped during another process step (
If needed, a dewetting layer 14 of titanium may also be applied to the rear side at the via entry openings, namely, a titanium layer having a thickness of 100 nm, said layer being sputtered onto the existing gold layer 13. The dewetting layer 14 is applied in a textured manner to the wafer, whereby a shadow mask is being used. The shadow mask consists of a metal foil having a thickness of 0.1 mm, whereby a laser is used to drill openings into said foil. The layout of the openings in the metal foil corresponds to the arrangement of the micro-vias 7 on the wafer. The diameter of the openings in the shadow mask are slightly larger than the entry diameter of the micro-vias 7 on the rear side of the wafer, so that a titanium ring having a width of approximately 40 μm is formed around the via entry opening. With the use of four additional through bores each at the end of the shadow mask and the wafer, both parts are adjusted relative to each other by means of alignment pins, i.e., said parts are aligned in a congruent manner.
It should be noted that the protective varnish 9 may also be stripped after the deposition of the dewetting layer 14 (titanium dewetting layer).
An ITO masking of the surface (protective layer 10) may also be omitted if a controlled reduction of the material thickness during the etching process is acceptable, i.e., the steps in accordance with
In this case, the total thickness of the wafer is reduced due to the large-area removal of the SiC. Considering an etching duration of approximately 2 hours, the wafer thickness is reduced from 390 μm to 250-300 μm. At the bottom of the hole, an edge length of 35-70 μm is obtained, whereby the corners are widened hexagonally. The shape of the hole is conical, with a clear widening of the cross-section at the entry, thus facilitating the subsequent coating of the hole wall with metal.
In view of the ablation rate, flexibility and reliability, a frequency-tripled Nd:YAG laser is well-suited for machining the extremely hard and chemically inert SiC. This laser delivers high-energy nanosecond pulses in the ultraviolet region of the spectrum at a wavelength of 355 nm and with pulse frequencies of up to 100 kHz. The laser beam is moved with micrometer accuracy by combining a CNC-controlled movement of the sample table and the beam deflection with a galvo scanner. With the use of image recognition and a highly accurate air-cushioned XY cross table, the laser beam can be positioned with an accuracy of ±1 μm relative to the existing structures on the workpiece. This precision is even achieved when laser texturing occurs on the rear side and the adjustment marks are located on the front side (located on the bottom).
The laser was used to drill pocket holes having a square cross-section and a hole bottom that is as flat as possible. The edge length was approximately 75 μm at the laser entry opening; at the hole bottom, it was approximately 15 μm; approximately 40 μm SiC were left below the hole bottom.
An automated drilling process was used, whereby the respective machining site of the sample was positioned under the beam exit in that the sample table was precisely moved with micrometer accuracy, and then the laser beam was rapidly moved by means of a mirror system (galvo scanner) on the workpiece, whereby an SiC having a thickness of 250-450 μm was used. When viewed in the scanning electron microscope, it can be easily seen that the laser-drilled holes are slightly conical and that a smooth wall with a minimum of deposits can be produced.
Resistance measurements performed on an SiC sample confirmed that a low-ohmic connection can be established between the two sides. To do so, the entire surface of one side of a sample was first metallized with a gold layer having a thickness of 5 μm. Then, from the other side, a matrix of vias was drilled as described above. The distance between the holes was 500 μm. Before measuring the resistance through a single hole, the individual holes had to be electrically separated from each other. To achieve this, the gold layer was severed (scratched) to obtain fields having a size of 500×500 μm2, each field having one via. Highly homogeneous contacting through the SiC sample could be demonstrated with good reproducibility. The resistance values are at 25-31 mΩ. The mean value across the 206 micro-vias is at 27±2 mΩ. The implementable hollow rivets display an aspect ratio of 3-4.
In tests with setup transistors of different types, the functionality of the devices was demonstrated. With reference to the characteristic lines of the transistors, proof was provided of the successful implementation of laser-drilled micro-vias in GaN process technology.
Technological investigations show that it is possible to implement laser-drilled micro-vias through monocrystalline SiC wafer material for high-performance GaN field effect transistors. Proof could be provided that laser-generated micro-texturing can be successfully implemented in device process-technology.
The prerequisite for the application of laser micro-machining in processing semiconductor wafers is the high positioning-accuracy of the beam center of ±1 μm and better. This accuracy relates to beam positioning relative to the existing device structures and must be achieved when machining the front side, as well as when machining the rear side.
The invention allows through-hole plating of the very hard and chemically stable silicon carbide. An aspect ratio of 3-4 was demonstrated therefor.
Number | Date | Country | Kind |
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10 2005 042 074.5 | Aug 2005 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP06/64599 | 7/24/2006 | WO | 00 | 12/21/2007 |