Abstract: During the formation of a complex metallization system, the influence of a manufacturing environment on sensitive barrier/seed material systems may be monitored or controlled by using an appropriate test pattern and applying an appropriate test strategy. For example, actual probe and reference substrates may be prepared and may be processed with and without exposure to the manufacturing environment of interest, thereby enabling an efficient evaluation of one or more parameters of the environment. Furthermore, an “optimized” manufacturing environment may be obtained on the basis of the test strategy disclosed herein.

Abstract: In complex metallization systems of sophisticated semiconductor devices, appropriate stress compensation mechanisms may be implemented in order to reduce undue substrate deformation during the overall manufacturing process. For example, additional dielectric material and/or functional layers of one or more metallization layers may be provided with appropriate internal stress levels so as to maintain substrate warpage at a non-critical level, thereby substantially reducing yield losses in the manufacturing process caused by non-reliable attachment of substrates to substrate holders in process and transport tools.

Abstract: A conductive barrier material of a metallization system of a semiconductor device may be formed on the basis of one or more deposition/etch cycles, thereby providing a reduced material thickness in the bevel region, while enhancing overall thickness uniformity in the active region of the semiconductor substrate. In some illustrative embodiments, two or more deposition/etch cycles may be used, thereby providing the possibility to select reduced target values for the barrier thickness in the die regions, while also obtaining a significantly reduced thickness in the bevel region.

Abstract: For providing control of two-step or a multi-step deposition process, a method and a corresponding deposition system is provided comprising providing a deposition process having at least two sub-processes employing different sets of process parameters, wherein each set of process parameters comprises at least one process parameter. The method comprises controllably generating an actual value for at least one first process parameter by taking into account at least one previous value of the respective first process parameter, wherein each first process parameter is a process parameter of said at least two sets of process parameters.

Abstract: A method comprises providing a semiconductor structure. The semiconductor structure comprises a feature comprising a first material and a layer of a second material formed over the feature. The semiconductor structure is exposed to an etchant. The etchant is adapted to selectively remove the first material, leaving the second material substantially intact. After exposing the semiconductor structure to the etchant, it is detected whether the feature has been affected by the etchant.

Abstract: By forming a thin passivation layer after the formation of openings connecting to a highly reactive metal region, any queue time effects may be significantly reduced. Prior to the deposition of a barrier/adhesion layer, the passivation layer may be efficiently removed on the basis of a heat treatment so as to initiate material removal by evaporation.

Abstract: By providing a tungsten nitride barrier layer for a contact plug, well-approved copper-based via formation techniques may be used to form a highly conductive contact plug, thereby significantly reducing the series resistance compared to conventional tungsten-based contact plugs. The tungsten nitride barrier layer may be deposited by ALD techniques, which exhibit superior step coverage and thus allow a reliable coverage of exposed surfaces of the contact opening, thereby providing the potential for using copper or copper alloys even in the vicinity of highly sensitive device areas of circuit elements, such as transistors and the like.

Abstract: By providing a conductive capping layer for metal-based interconnect lines, an enhanced performance with respect to electromigration may be achieved. Moreover, a corresponding manufacturing technique is provided in which via openings may be reliably etched into the capping layer without exposing the underlying metal, such as copper-based material, thereby also providing enhanced electromigration performance, especially at the transitions between copper lines and vias.

Abstract: By providing a stiffening layer at three sidewalls of a trench to be filled with a copper-containing metal, the reduced thermomechanical confinement of a low-k material may be compensated for, at least to a certain degree, thereby reducing electromigration effects and hence increasing lifetime of sophisticated semiconductor devices having metallization layers including low-k dielectric materials in combination with copper-based metal lines.

Abstract: In a method of forming a semiconductor structure, an opening is formed in a layer of a dielectric material provided over an electrically conductive feature. An etching process is performed in order to form a recess in the electrically conductive feature. The bottom of the recess may have a rounded shape. The recess and the opening are filled with an electrically conductive material. Due to the provision of the recess, electromigration, stress migration and a local heating of the semiconductor structure, which may adversely affect the functionality of the semiconductor structure, can be reduced.

Abstract: A cleaning process for cleaning the surface of a substrate is disclosed, wherein the surface comprises portions of a dielectric material and portions of a conductive material. According to the method disclosed, the temperature at the surface of the substrate is kept below a predefined value during the actual cleaning step in a reactive and/or inert plasma ambient, such as an argon gas ambient, wherein the predefined value corresponds to the surface temperature at which agglomeration of the conductive material occurs.

Abstract: The invention provides a technique of monitoring the void formation in a damascene interconnection process. According to the invention, a test structure is provided that includes at least two damascene structures that have at least one different cross-sectional geometric parameter. To monitor the void formation, the test structure is cut to expose a cross-sectional view to the damascene structures. The cross-sectional view is then inspected and the void formation is investigated in each of the damascene structures. The invention is particularly applicable to multi-level copper-based dual-damascene interconnection processes to monitor the voiding at the interface between barrier layers and bottom metal trenches. The invention allows monitoring of the void formation by locating only one structure on the chip and performing only one cut.

Abstract: A cleaning process for cleaning the surface of a substrate is disclosed, wherein the surface comprises portions of a dielectric material and portions of a conductive material. According to the method disclosed, the temperature at the surface of the substrate is kept below a predefined value during the actual cleaning step in a reactive and/or inert plasma ambient, such as an argon gas ambient, wherein the predefined value corresponds to the surface temperature at which agglomeration of the conductive material occurs.

Abstract: For determining the quality of interconnections in integrated circuits, especially in damascene applications, a method of monitoring voids is disclosed, wherein a barrier metal layer is directly deposited on a planarized metal to provide a large-area surface that is not required to be destroyed for further analysis of the interface between the metal and the barrier metal layer. The analysis may be carried out by employing an electron microscope operated in a back-scatter mode.

Abstract: In an in situ damascene metallization process employing a barrier layer between the metal and the dielectric, the generation of voids, especially at the bottom of vias, can be significantly reduced or even completely avoided by maintaining the surface temperature below a critical temperature during deposition of the barrier material.

Abstract: The invention provides a technique of monitoring the void formation in a damascene interconnection process. According to the invention, a test structure is provided that includes at least two damascene structures that have at least one different cross-sectional geometric parameter. To monitor the void formation, the test structure is cut to expose a cross-sectional view to the damascene structures. The cross-sectional view is then inspected and the void formation is investigated in each of the damascene structures. The invention is particularly applicable to multi-level copper-based dual-damascene interconnection processes to monitor the voiding at the interface between barrier layers and bottom metal trenches. The invention allows monitoring of the void formation by locating only one structure on the chip and performing only one cut.

Abstract: In an in situ damascene metallization process employing a barrier layer between the metal and the dielectric, the generation of voids, especially at the bottom of vias, can be significantly reduced or even completely avoided by maintaining the surface temperature below a critical temperature during deposition of the barrier material.

Abstract: For determining the quality of interconnections in integrated circuits, especially in damascene applications, a method of monitoring voids is disclosed, wherein a barrier metal layer is directly deposited on a planarized metal to provide a large-area surface that is not required to be destroyed for further analysis of the interface between the metal and the barrier metal layer. The analysis may be carried out by employing an electron microscope operated in a back-scatter mode.