Abstract: A hardmask stack is comprised of alternating layers of doped amorphous carbon and undoped amorphous carbon. The undoped amorphous carbon layers serve as buffer layers that constrain the effects of compressive stress within the doped amorphous carbon layers to prevent delamination. The stack is provided with a top capping layer. The layer beneath the capping layer is preferably undoped amorphous carbon to reduce photoresist poisoning. An alternative hardmask stack is comprised of alternating layers of capping material and amorphous carbon. The amorphous carbon layers may be doped or undoped. The capping material layers serve as buffer layers that constrain the effects of compressive stress within the amorphous carbon layers to prevent delamination. The top layer of the stack is formed of a capping material. The layer beneath the top layer is preferably undoped amorphous carbon to reduce photoresist poisoning.

Abstract: An exemplary method of fabricating an integrated circuit can include depositing a reflective metal material layer over a layer of polysilicon, depositing an anti-reflective coating over the reflective metal material layer, trim etching the anti-reflective coating to form a pattern, etching the reflective metal material layer according to the pattern, and removing portions of the polysilicon layer using the pattern formed from the removed portions of anti-reflective coating.

Abstract: In one embodiment, the present invention relates to a method of forming a shallow trench, involving the steps of providing a semiconductor substrate comprising a barrier oxide layer over at the semiconductor substrate and a nitride layer over the barrier oxide layer; depositing an ultra-thin photoresist over the nitride layer, the ultra-thin photoresist having a thickness of about 2,000 Å or less; patterning the ultra-thin photoresist to expose a portion of the nitride layer and to define a pattern for the shallow trench; etching the exposed portion of the nitride layer with an etchant having a nitride:photoresist selectivity of at least about 10:1 to expose a portion of the barrier oxide layer; etching the exposed portion of the barrier oxide layer to expose a portion of the semiconductor substrate; and etching the exposed portion of the semiconductor substrate to provide the shallow trench.

Abstract: A method of utilizing a multilayer photoresist to form contact holes and/or conductors utilizing a dual damascene process includes utilizing layered photoresists. A contact in a conductive line can be formed in a single deposition step or in a two-stage deposition step. Image layers can remain as part of the interconnect structure or be removed by a polishing technique. The process can be utilized for any conductive structures provided above a substrate of an integrated circuit.

Abstract: A method of using an amorphous carbon layer for improved reticle fabrication includes depositing a stack of layers including a substrate, an absorber, a transfer layer, an anti-reflective coating (ARC) layer, and a photoresist layer, patterning the photoresist layer, and etching the ARC layer and the transfer layer. The method also includes etching the absorber layer and removing the transfer layer. The transfer layer including amorphous carbon.

Abstract: A method of determining overlay layers utilizing advanced lithographic materials utilizes a post-etch overlay metrology. After etching, a relatively opaque layer is removed so that registration markers such as trench isolation structures can be observed. Lithographic parameters associated with the process can be adjusted in accordance with the observations. In a preferred embodiment, an overlay error is determined and adjustments are made to the reduce the overlay error.

Abstract: To reduce the width of a MOSFET gate, the gate is formed with a hardmask formed thereupon. An isotropic etch is then performed to trim the gate in order to reduce the width of the gate. The resulting gate may be formed with a width that is narrower than a minimum width achievable solely through conventional projection lithography techniques.

Abstract: In a process for forming a photoresist mask, a photoresist layer is applied to a substrate. A silyated layer is formed in the photoresist layer. The features of the silyated area correspond to the features of a photoresist mask to be formed. The photoresist layer is then etched to form a photoresist base beneath the silyated area. The photoresist base is etched to remove material from its sides such that it becomes narrower than the silyated area. The silyated area is then removed, leaving a photoresist mask on the substrate.

Abstract: A hardmask stack is comprised of alternating layers of doped amorphous carbon and undoped amorphous carbon. The undoped amorphous carbon layers serve as buffer layers that constrain the effects of compressive stress within the doped amorphous carbon layers to prevent delamination. The stack is provided with a top capping layer. The layer beneath the capping layer is preferably undoped amorphous carbon to reduce photoresist poisoning. An alternative hardmask stack is comprised of alternating layers of capping material and amorphous carbon. The amorphous carbon layers may be doped or undoped. The capping material layers serve as buffer layers that constrain the effects of compressive stress within the amorphous carbon layers to prevent delamination. The top layer of the stack is formed of a capping material. The layer beneath the top layer is preferably undoped amorphous carbon to reduce photoresist poisoning.

Abstract: One aspect of the present invention relates to a method of dual damascene processing, involving forming a plurality of via openings in the insulation structure containing a single layer of a dielectric material; and simultaneously (i) forming a plurality of trenches in the insulation structure, each trench positioned along the substantially straight line of a group of via openings, and (ii) monitoring the formation of trenches using a scatterometry system to determine trench depth, and terminating forming the trenches when a desired trench depth is attained.

Abstract: One aspect of the invention relates to a metal fill process and systems therefor involving providing a standard calibration wafer having a plurality of fill features of known dimensions in a metalization tool; depositing a metal material over the standard calibration wafer; monitoring the deposition of metal material using a sensor system, the sensor system operable to measure one or more fill process parameters and to generate fill process data; controlling the deposition of metal material to minimize void formation using a control system wherein the control system receives fill process data from the sensor system and analyzes the fill process data to generate a feed-forward control data operative to control the metalization tool; and depositing metal material over a production wafer in the metalization tool using the fill process data generated by the sensor system and the control system. The invention further relates to tool characterization processes and systems therefor.

Abstract: A process for forming a semiconductor device may comprise forming an organic dielectric layer on a substrate, forming a protective layer on the organic dielectric layer, forming a photoresist mask on the protective layer, and silyating the photoresist mask. The protective layer is etched using the silyated photoresist mask as an etch mask, and then the organic dielectric layer is etched using the silyated photoresist mask as an etch mask. Metal may be deposited in a void etched in the organic dielectric layer to form a wiring, contact or via.

Abstract: A method of making organic memory cells made of two electrodes with a controllably conductivce media between the two electrodes is disclosed. The controllably conductive media contains an organic semiconductor layer and passive layer. The organic semiconductor layer is formed using spin-on techniques with the assistance of certain solvents.

Abstract: One aspect of the present invention relates to a system and method for controlling thermal expansion on an EUV mask during EUV photolithography. The system includes an EUV photolithography system for irradiating one or more layers of a wafer through one or more gratings of a patterned EUV mask, whereby heat accumulates on at least a portion of the patterned EUV mask during the irradiation of the one or more layers of the wafer; an EUV mask inspection system for monitoring the one or more gratings on the mask to detect expansion therein, the inspection system producing data relating to the mask; and a temperature control system operatively coupled to the inspection system for making adjustments to the EUV photolithography system in order to compensate for the detected expansion on the mask. The method involves employing feedback and feed forward control to optimize the current and future EUV photolithography processes.

Abstract: One aspect of the present invention relates to a feedback-driven, closed loop system/method for obtaining consistently formed semiconductor structures. The system/method involves controlling the progression of a lithography process such as a deposition or etching process. The system employs one or more piezoelectric sensors, such as quartz crystal sensors, integrated on a wafer. During the lithography process, the sensors produce frequency data which is analyzed and communicated to a lithography process controller in order to modulate one or more process parameters and/or one or more process components. The frequency data indicates the progression of the lithography process and facilitates determining whether the parameters/components need correction to obtain structures which are consistent throughout the wafer and from wafer to wafer.

Abstract: There is provided a method for forming a photoresist layer for photolithographic applications which has increased structural strength. The photoresist layer is exposed through a mask and developed. The photoresist layer is then treated to change its material properties before the photoresist layer is dried. Also provided are a semiconductor fabrication method employing a treated photoresist and a composition for a treatable photoresist.

Abstract: A method of forming an etch mask includes patterning a top surface of a photoresist layer, carbonizing the patterned top surface of the photoresist layer and selectively removing portions of the photoresist layer. Portions of the photoresist layer under the carbonized areas remain. A substrate or a layer above substrate can be etched or processed in accordance with the mask formed from the photoresist layer.

Abstract: A pellicle utilizes a film attached to a barrier layer above a substrate. The film is relatively transparent to radiation in the EUV range. The substrate and barrier layer are coupled to a periphery of the film and is exclusive of the center portion of the film. The pellicle can be manufactured by growing a relatively transparent film on a barrier layer that is grown on a substrate. The substrate and barrier layer are etched to expose a portion of the relatively transparent film.

Abstract: Disclosed is a wafer containing a semiconductor substrate, at least one metal layer formed over the semiconductor substrate, and at least one electrical sensor embedded at least one of on and in the wafer to facilitate real time monitoring of the metal layer as it progresses through a subtractive metallization process. The system contains a wafer comprising at least one metal layer formed on a semiconductor substrate, at least one electrical sensor in contact with the wafer and operable to detect and transmit electrical activity associated with the wafer, and an electrical measurement station operable to process electrical activity detected and received from the electrical sensor for monitoring a subtractive metallization process in real-time.

Abstract: The present invention relates to a method for fabricating interconnecting lines and vias in a layer of insulating material. A via is formed in the layer of insulating material. A protective material is formed so as to be conformal to at least edges and sidewalls of the via, the protective material facilitating shielding of at least the edges and sidewalls of the via from a trench etch step. The trench etch step is performed to form a trench opening in the insulating material. The via and trench are filled with a conductive metal.