Abstract: A reflective semiconductor device includes an integrated circuit (IC) structure, and a pair of mirror elements over the IC structure. The pair of mirror elements are separated by a trench. Each mirror element includes a mirror layer of, for example, aluminum, on the IC structure, and a low temperature oxide (LTO) layer on the mirror layer. A high temperature oxide (HTO) layer is over the pair of mirror elements and fills the trench. A liquid crystal layer over the mirror elements provides a liquid crystal on semiconductor (LCOS) device. The two-oxide layer prevents mirror layer creep and/or agglomeration during formation of the HTO layer and provide a suitable surface for LCOS assembly without using specialized alloys.

Abstract: In a method of forming a three-dimensional semiconductor device, a first chip is provided that includes a first substrate, a first device layer positioned on and covering the first substrate, and a first metallization system positioned on and covering the first device layer, wherein the first device layer includes a plurality of first transistor elements. A second chip is also provided and includes a second substrate, a second device layer positioned on and covering the second substrate, and a second metallization system positioned on and covering the second device layer, wherein the second device layer includes a plurality of second transistor elements. The second chip is attached to the first chip so that a heat spreading material is positioned between the first chip and the second chip and covers at least a portion of the first metallization system.

Abstract: In a method of forming a three-dimensional semiconductor device, a first chip is provided that includes a first substrate, a first device layer positioned on and covering the first substrate, and a first metallization system positioned on and covering the first device layer, wherein the first device layer includes a plurality of first transistor elements. A second chip is also provided and includes a second substrate, a second device layer positioned on and covering the second substrate, and a second metallization system positioned on and covering the second device layer, wherein the second device layer includes a plurality of second transistor elements. The second chip is attached to the first chip so that a heat spreading material is positioned between the first chip and the second chip and covers at least a portion of the first metallization system.

Abstract: In a three-dimensional chip configuration, a heat spreading material may be positioned between adjacent chips and also between a chip and a carrier substrate, thereby significantly enhancing heat dissipation capability. Furthermore, appropriately sized and positioned through holes in the heat spreading material may enable electrical chip-to-chip connections, while responding thermally conductive connectors may extend to the heat sink without actually contacting the corresponding chips.

Abstract: In a semiconductor device or test structure, appropriate heating elements, for instance in the form of resistive structures, are implemented so as to obtain superior area coverage, thereby enabling a precise evaluation of the thermal conditions within a complex semiconductor device. In particular, the device internal heating elements may allow the evaluation of hot spots and the response of a complex metallization system to specific temperature profiles, in particular at critical areas, such as edge regions in which mechanical stress forces are typically highest in contact regimes in which the package substrate and the metallization system are directly connected.

Abstract: In a semiconductor device, through hole vias or through silicon vias (TSV) may be formed so as to include an efficient stress relaxation mechanism, for instance provided on the basis of a stress relaxation layer, in order to reduce or compensate for stress forces caused by a pronounced change in volume of the conductive fill materials of the through hole vias. In this manner, the high risk of creating cracks and delamination events in conventional semiconductor devices may be significantly reduced.

Abstract: In a reflow process for connecting a semiconductor die and a package substrate, the temperature gradient and thus the thermally induced mechanical forces in a sensitive metallization system of the semiconductor die may be reduced during the cooling phase. To this end, one or more heating intervals may be introduced into the cooling phase, thereby efficiently reducing the temperature difference. In other cases, the central region may additionally be cooled by providing appropriate locally restricted mechanisms, such as a locally restricted gas flow and the like. Consequently, desired short overall process times may be obtain without contributing to increased yield losses when processing sophisticated metallization systems on the basis of a lead-free contact regime.

Abstract: A stress compensation region that may be appropriately positioned on a package substrate may compensate for or at least significantly reduce the thermally induced mechanical stress in a sensitive metallization system of a semiconductor die, in particular during the critical reflow process. For example, a stressor ring may be formed so as to laterally surround the chip receiving portion of the package substrate, wherein the stressor ring may efficiently compensate for the thermally induced deformation in the chip receiving portion.

Abstract: A semiconductor chip and a package substrate may be directly connected on the basis of form closure by providing appropriately shaped complementary contact structures in the semiconductor chip and the package substrate. Consequently, solder material may no longer be required and thus any elevated temperatures during the assembly process may be avoided, which may conventionally result in significant stress forces, thereby creating damage, in particular in very complex metallization systems.

Abstract: The metallization system of complex semiconductor devices may be evaluated in terms of mechanical integrity on the basis of a measurement system and measurement procedures in which individual contact elements, such as metal pillars or solder bumps, are mechanically stimulated, while the response of the metallization system, for instance in the form of directly measured forces, is determined in order to quantitatively evaluate mechanical status of the metallization system. In this manner, the complex material systems and the mutual interactions thereof may be efficiently assessed.

Abstract: In sophisticated semiconductor devices, densely packed metal line layers may be formed on the basis of an ultra low-k dielectric material, wherein corresponding modified portions of increased dielectric constant may be removed in the presence of the metal lines, for instance, by means of a selective wet chemical etch process. Consequently, the metal lines may be provided with desired critical dimensions without having to take into consideration a change of the critical dimensions upon removing the modified material portion, as is the case in conventional strategies.

Abstract: By forming a protection layer prior to the application of the planarization layer during a dual damascene strategy for first patterning vias and then trenches, enhanced etch fidelity may be accomplished. In other aspects disclosed herein, via openings and trenches may be patterned in separate steps, which may be accomplished by different etch behaviors of respective dielectric materials and/or the provision of an appropriate etch stop layer, while filling the via opening and the trench with a barrier material and a highly conductive metal may be achieved in a common fill sequence. Hence, the via opening may be formed on the basis of a reduced aspect ratio, while nevertheless providing a highly efficient overall process sequence.

Abstract: In a three-dimensional chip configuration, a heat spreading material may be positioned between adjacent chips and also between a chip and a carrier substrate, thereby significantly enhancing heat dissipation capability. Furthermore, appropriately sized and positioned through holes in the heat spreading material may enable electrical chip-to-chip connections, while responding thermally conductive connectors may extend to the heat sink without actually contacting the corresponding chips.

Abstract: In a semiconductor device or test structure, appropriate heating elements, for instance in the form of resistive structures, are implemented so as to obtain superior area coverage, thereby enabling a precise evaluation of the thermal conditions within a complex semiconductor device. In particular, the device internal heating elements may allow the evaluation of hot spots and the response of a complex metallization system to specific temperature profiles, in particular at critical areas, such as edge regions in which mechanical stress forces are typically highest in contact regimes in which the package substrate and the metallization system are directly connected.

Abstract: A semiconductor chip and a package substrate may be directly connected on the basis of form closure by providing appropriately shaped complementary contact structures in the semiconductor chip and the package substrate. Consequently, solder material may no longer be required and thus any elevated temperatures during the assembly process may be avoided, which may conventionally result in significant stress forces, thereby creating damage, in particular in very complex metallization systems.

Abstract: In a semiconductor device, through hole vias or through silicon vias (TSV) may be formed so as to include an efficient stress relaxation mechanism, for instance provided on the basis of a stress relaxation layer, in order to reduce or compensate for stress forces caused by a pronounced change in volume of the conductive fill materials of the through hole vias. In this manner, the high risk of creating cracks and delamination events in conventional semiconductor devices may be significantly reduced.

Abstract: In sophisticated semiconductor devices, densely packed metal line layers may be formed on the basis of an ultra low-k dielectric material, wherein corresponding modified portions of increased dielectric constant may be removed in the presence of the metal lines, for instance, by means of a selective wet chemical etch process. Consequently, the metal lines may be provided with desired critical dimensions without having to take into consideration a change of the critical dimensions upon removing the modified material portion, as is the case in conventional strategies.

Abstract: In a three-dimensional chip configuration, a heat spreading material may be positioned between adjacent chips and also between a chip and a carrier substrate, thereby significantly enhancing heat dissipation capability. Furthermore, appropriately sized and positioned through holes in the heat spreading material may enable electrical chip-to-chip connections, while responding thermally conductive connectors may extend to the heat sink without actually contacting the corresponding chips.

Abstract: A stress compensation region that may be appropriately positioned on a package substrate may compensate for or at least significantly reduce the thermally induced mechanical stress in a sensitive metallization system of a semiconductor die, in particular during the critical reflow process. For example, a stressor ring may be formed so as to laterally surround the chip receiving portion of the package substrate, wherein the stressor ring may efficiently compensate for the thermally induced deformation in the chip receiving portion.

Abstract: In a reflow process for connecting a semiconductor die and a package substrate, the temperature gradient and thus the thermally induced mechanical forces in a sensitive metallization system of the semiconductor die may be reduced during the cooling phase. To this end, one or more heating intervals may be introduced into the cooling phase, thereby efficiently reducing the temperature difference. In other cases, the central region may additionally be cooled by providing appropriate locally restricted mechanisms, such as a locally restricted gas flow and the like. Consequently, desired short overall process times may be obtain without contributing to increased yield losses when processing sophisticated metallization systems on the basis of a lead-free contact regime.