1. Technical Field
The present invention relates to a semiconductor unit incorporating a submount, and more particularly to a submount for supporting a semiconductor device.
2. Known Art
The layer 4 has two important functions. One of the functions includes bonding base 2 and chip 8 while spreading out heat from the chip's operation. The other function includes providing electro-conductivity between the contacts, as known by one of ordinary skill in the art.
The temperatures reached during the operation of chip 8 are typically high. Since thermo-conductivity of base 2 is lower than that one of adjacent Au metal layer 4, cyclical temperature changes cause substantial stresses on device 7. These stresses may lower the reliability of device 7.
Turning again to
The electrode gold (Au) layer 4 facilitates the severity of elevated temperatures during the operation of the unit by spreading the generated heat over a portion of surface while guiding the heat through base 2 towards a heat sink. However, the thermo- and electro-conductive surface of Au layer 4 is rather small which impedes the heat spreading process. Besides, the electrical resistivity of Au layer is appreciable.
It is therefore desirable to manufacture a cost effective semiconductor unit.
It is further desirable to configure a semiconductor unit of the type disclosed herein which can efficiently spread heat generated during manufacturing and operation of the unit.
It is still further desirable to configure a semiconductor unit of the type disclosed herein which has a high power conversion efficiency.
It is also desirable to provide a process for manufacturing a semiconductor unit distinguished by its thermal efficiency and low manufacturing costs.
The above articulated needs are met by a semiconductor unit and a method for configuring the unit as disclosed hereinbelow. In accordance with one of salient features of the disclosures, a typically relatively thick gold (Au) layers is substantially replaced with a silver (Ag) layer. The use of an Ag layer translates into substantial cost savings and enhanced performance and reliability of the semiconductor unit through the reduced thermal loading, all of which lead to a high power conversion efficiency (“PCE”).
Typically materials of different layers composing a submount of semiconductor unit have respective coefficients of thermal expansion (“CTE”) which differ from one another and from materials used for manufacturing a chip. As a rule, the base of semiconductor units has a CTE lower than that one of the Ag layer. Thus the layers of the submount may be configured so that their cumulative CTE substantially matches the CTE of the material of the chip. Once this condition is met, the generation of mechanical stresses is considerably minimized.
In accordance with one embodiment of the disclosure configured to minimize stresses, the inventive unit is configured with a controlled thickness of Ag layer which is deposited atop the base by any known process, such as electroplating. The desired thickness of the Ag layer is determined so that a cumulative CTE of the submount substantially matches that one of material used for configuring a chip.
A further embodiment includes a layer of plastic/malleable material deposited between the chip and Ag layer. The soft material layer is configured so that it may reduce mechanical stresses on the chip even if the thickness of the Ag layer is arbitrary. Of course, both techniques may be combined.
The above and other features and advantages of the disclosed unit will become more readily apparent from the following specific description accompanied by following drawings, in which:
The reference will now be made in detail to the disclosed configurations. The drawings are far from precise scale and do not show well known to an artisan in semiconductor industry additional layers. The word “couple” and similar terms do not necessarily denote direct and immediate connections, but also include connections through intermediate elements.
The Ag layer 14 not only renders the disclosed unit cost-effective, but it also renders the unit most thermo- and electro-efficient. The thermoconductivity of silver is higher than that of gold, whereas its electro-resistivity is lower. As known, a thermo-conducting surface is a function of material. Accordingly, the heat, which is generated when chip 20 is in use by an active zone 16, spreads out across a surface A2 of Ag layer 14 which is greater than surface A1 of Au layer 2 in
The thickness of deposited heat-spreading and electro-conducting Ag layer 14 should be controlled since it directly correlates to a coefficient of thermal expansion of the submount components and material of chip 20. Consequently, if a cumulative coefficient of thermal expansion of submount 10 substantially matches that one of material of chip 20, mechanical stresses affecting disclosed device 20, can be substantially reduced. The following equation fairly characterizes the determination of Ag layer's thickness:
where K is a coefficient of thermal expansion and D is a thickness of any given layer of submount 10. Accordingly, since thermal expansion coefficients for respective materials are known, it is easy to determine a thickness of Ag provided the thickness of each of the submount layers is known. Consider the following example.
A coefficient of expansion of Ag is 19.5, coefficient of base 12 which, for example is made from aluminum nitride (AlN) is 4.5 and coefficient of expansion of GaAs—exemplary material of chip 20—is 5.8. Assume further that a thickness D of base layer 12 is 300 micron. Accordingly, the thickness of Ag layer 14 should be selected so that the cumulative coefficient of expansion of submount 10 was 5.8. Using the above-disclosed equation, Ag layer 14 should have the following thickness X.
The Ag layer is approximately 28 microns thick. Accordingly, in the given example, the 28 micron thick Ag layer provides minimal mechanical stresses acting on chip 20.
In summary, a thick Ag layer deposited on submount, which may be made from ceramics, metals and other suitable materials, dramatically reduces manufacturing costs of the semiconductor unit of the type disclosed herein above. Furthermore, if a thickness of Ag layer is determined in accordance with the equation, chip 20 may be protected from mechanical stresses generated during heating/cooling manufacturing stages. Finally, a specifically configured soft layer may also be sufficient to largely reduce the mechanical stresses even if the Ag layer has an arbitrary thickness.
The present disclosure is not restricted to particular configurations which are described here. It is apparent that departure from specific structures and configurations as described and shown will suggest themselves to those skilled in the art and may be used without departing from the scope of the disclosure, as defined in the following claims.
Number | Date | Country | Kind |
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PCT/US2011/040901 | Jun 2011 | US | national |