This invention relates to semiconductor device processing, and more specifically relates to the selective ablation and thinning of semiconductor wafers, to wafers so produced, and to laser ablation techniques for semiconductor wafers.
Semiconductor die are commonly simultaneously processed and formed in the surface of a wafer of silicon or other semiconductor material, and are subsequently separated from one another in a subsequent dicing operation.
If the die conduct vertically between the top and bottom surfaces, the die thickness presents electrical resistance (RDSON). In order to reduce RDSON it is common to thin the wafer, for example from about 350 μm to 50 μm or less.
The wafer thinning operation uses mechanical grinding or wet etching. Both of these processes are complex, time consuming and expensive. Further, excessive or incorrect thinning may lead to weak, fragile, thin wafers that break or fracture easily during production, installation or use.
A laser ablated wafer for a semiconductor device, and a method of producing such a wafer to achieve a lower electrical resistance, are provided. The method includes forming a standard device on a first surface of the wafer and focusing a laser to form holes or trenches on a bottom surface of the wafer, and filling the holes or trenches to provide conductive surfaces for the semiconductor device.
In such a wafer each hole or trench on the second surface may be much deeper and wider than those on the first surface. For example, each trench on the second surface may be hundreds of microns deep and tens of microns wide. Such a substrate may be approximately 350 μm or less in thickness.
The method may further entail etching or grating (or both) at least one of the first surface or the second surface before the laser ablation.
The filling of the holes or trenches may be a metallic material, such as aluminum or aluminum alloy.
In accordance with the invention, a plurality of standard devices 20 are formed in surface 11, that is, on the top surfaces of a wafer 10. The standard devices may be formed and provided with electrodes according to the conventional processes, and the entire active region above the substrate may be formed before the laser ablation. For example, gate structures with an insulation layer inside trenches around electrodes may be formed in the top surface for a vertical conduction MOSFET or other power device.
The laser beam (not shown) is sharply focused to form second trenches 23 on the bottom surface of the wafer 10. The wafer 10 can be somewhat pre-thinned using conventional techniques, such as grinding and/or etching, before the laser ablation to reduce the depth needed for the ablated holes. However, the wafer 10 remains thick enough to retain sufficient mechanical strength for easy handling of the wafer without fracture.
The trenches 23 may be back-filled with a metal, for example, aluminum, after forming to provide conductive surfaces for the die to connect with contacts outside the die, such as contacts of a circuit board or frame or other die. As shown in
The wafer 10 of
For example, the electrical contacts of the die may be comprised of the fillings in the holes or trenches 23, the deeper and wider trenches formed on the second surface of the die, while the fillings of the first trenches 21 of the first surface 11 may comprise only gate electrodes of the die. However, it will be understood that not every trench need contain an electrical contact or an active electrode structure of the die. That is, depending on the needs of the ablation application, trenches may be provided that have no electrical contact function and/or no functioning electrode structure.
An example of a completed die is illustrated in
Such a die will typically have a reduced current path and an RDSON of a much thinner wafer than that of
Another embodiment of a completed die is illustrated in
Although the present invention has been described in relation to particular embodiments thereof, many other variations, combinations of features, and modifications and other uses will become apparent to those skilled in the art. It is preferred, therefore, that the present invention be limited not by the specific disclosure herein.
The present application claims priority from U.S. Provisional Application No. 60/748,891 filed on Dec. 9, 2005, which is incorporated in full by reference herein.
Number | Date | Country | |
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60748891 | Dec 2005 | US |