Abstract: The present invention provides systems and methods for simultaneous, parallel and/or rapid serial testing of material parameters or other parameters of the result of a process. The testing is typically used for screening different methods or materials to select those methods or materials with desired properties. A reactor structure used to form the materials may consist of an array of small isolated reaction chambers that overlie the substrate so that the substrate forms a bottom surface of each isolated reaction chamber. Test structures are formed on the substrate, where the location of each test structure corresponds to an isolated reaction chamber area of the reaction structure. Test structures are used to measure certain parameters, such as by probing contact pads for each test structure, or such testing may be performed in-situ during processing.

Abstract: Provided are semiconductor devices, such as resistive random access memory (ReRAM) cells, that include current limiting layers formed from alloys of transition metals. Some examples of such alloys include chromium containing alloys that may also include nickel, aluminum, and/or silicon. Other examples include tantalum and/or titanium containing alloys that may also include a combination of silicon and carbon or a combination of aluminum and nitrogen. These current limiting layers may have resistivities of at least about 1 Ohm-cm. This resistivity level is maintained even when the layers are subjected to strong electrical fields and/or high temperature processing. In some embodiments, the breakdown voltage of a current limiting layer is at least about 8V. The high resistivity of the layers allows scaling down the size of the semiconductor devices including these layers while maintaining their performance.

Abstract: Resistive switching memory elements are provided that may contain electroless metal electrodes and metal oxides formed from electroless metal. The resistive switching memory elements may exhibit bistability and may be used in high-density multi-layer memory integrated circuits. Electroless conductive materials such as nickel-based materials may be selectively deposited on a conductor on a silicon wafer or other suitable substrate. The electroless conductive materials can be oxidized to form a metal oxide for a resistive switching memory element. Multiple layers of conductive materials can be deposited each of which has a different oxidation rate. The differential oxidization rates of the conductive layers can be exploited to ensure that metal oxide layers of desired thicknesses are formed during fabrication.

Abstract: A current-limiting layer and a current-reducing layer are incorporated into a resistive switching memory device to form memory arrays. The incorporated current-limiting layer reduces the occurrence of current spikes during the programming of the resistive switching memory device and the incorporated current-reducing layer minimizes the overall current levels that can flow through the resistive switching memory device. Together, the two incorporated layers help improve device performance and lifetime.

Abstract: A resistor structure incorporated into a resistive switching memory cell or device to form memory devices with improved device performance and lifetime is provided. The resistor structure may be a two-terminal structure designed to reduce the maximum current flowing through a memory device. A method is also provided for making such memory device. The method includes depositing a resistor structure and depositing a variable resistance layer of a resistive switching memory cell of the memory device, where the resistor structure is disposed in series with the variable resistance layer to limit the switching current of the memory device. The incorporation of the resistor structure is very useful in obtaining desirable levels of device switching currents that meet the switching specification of various types of memory devices. The memory devices may be formed as part of a high-capacity nonvolatile memory integrated circuit, which can be used in various electronic devices.

Abstract: Provided are carbon doped resistive switching layers, resistive random access memory (ReRAM) cells including these layers, as well as methods of forming thereof. Carbon doping of metal containing materials creates defects in these materials that allow forming and breaking conductive paths as evidenced by resistive switching. Relative to many conventional dopants, carbon has a lower diffusivity in many suitable base materials. As such, these carbon doped materials exhibit structural stability and consistent resistive switching over many operating cycles. Resistive switching layers may include as much as 30 atomic percent of carbon, making the dopant control relatively simple and flexible. Furthermore, carbon doping has acceptor characteristics resulting in a high resistivity and low switching currents, which are very desirable for ReRAM applications. Carbon doped metal containing layer may be formed from metalorganic precursors at temperatures below saturation ranges of atomic layer deposition.

Abstract: A nonvolatile resistive memory element has a novel variable resistance layer that includes a metal nitride, a metal oxide-nitride, a two-metal oxide-nitride, or a multilayer stack thereof. One method of forming the novel variable resistance layer comprises an interlayer deposition procedure, in which metal oxide layers are interspersed with metal nitride layers and then converted into a substantially homogeneous layer by an anneal process. Another method of forming the novel variable resistance layer comprises an intralayer deposition procedure, in which various ALD processes are sequentially interleaved to form a metal oxide-nitride layer. Alternatively, a metal oxide is deposited, nitridized, and annealed to form the variable resistance layer or a metal nitride is deposited, oxidized, and annealed to form the variable resistance layer.

Abstract: Forming a resistive memory structure at a temperature well above the operating temperature can reduce the forming voltage and create a defect distribution with higher stability and lower programming voltages. The forming temperature can be up to 200 C above the operating temperature. The memory chip can include an embedded heater in the chip package, allowing for a chip forming process after packaging.

Abstract: Selector devices that can be suitable for memory device applications can have low leakage currents at low voltages to reduce sneak current paths for non selected devices, and high leakage currents at high voltages to minimize voltage drops during device switching. In some embodiments, the selector device can include a first electrode, a tri-layer dielectric layer, and a second electrode. The tri-layer dielectric layer can include a high leakage dielectric layer sandwiched between two lower leakage dielectric layers. The low leakage layers can function to restrict the current flow across the selector device at low voltages. The high leakage dielectric layer can function to enhance the current flow across the selector device at high voltages.

Abstract: CMOS imaging sensors having fluorine-passivated structures to reduce dark current are disclosed together with methods of making thereof. The CIS comprises an array of pixels on a substrate, each pixel comprising a pinned photodiode, an isolation trench adjacent to the pinned photodiode, and a plurality of transistors. Methods of preparing a CIS comprise providing a source of fluorine (F) atoms, and annealing in the presence of the source of F atoms. After the annealing, at least one silicon-containing surface or region in the CIS comprises Si—F bonds and is fluorine passivated.

Abstract: A nonvolatile resistive memory element includes an oxygen-gettering layer. The oxygen-gettering layer is formed as part of an electrode stack, and is more thermodynamically favorable in gettering oxygen than other layers of the electrode stack. The Gibbs free energy of formation (?fG°) of an oxide of the oxygen-gettering layer is less (i.e., more negative) than the Gibbs free energy of formation of an oxide of the adjacent layers of the electrode stack. The oxygen-gettering layer reacts with oxygen present in the adjacent layers of the electrode stack, thereby preventing this oxygen from diffusing into nearby silicon layers to undesirably increase an SiO2 interfacial layer thickness in the memory element and may alternately be selected to decrease such thickness during subsequent processing.

Abstract: Programming a resistive memory structure at a temperature well above the operating temperature can create a defect distribution with higher stability, leading to a potential improvement of the retention time. The programming temperature can be up to 100 C above the operating temperature. The memory chip can include embedded heaters in the chip package, allowing for heating the memory cells before the programming operations.

Abstract: An apparatus and method for testing electromigration in semiconductor devices includes providing an electromigration test structure, where the electromigration test structure includes a first metal line; a metal bridge operatively coupled to the first metal line; a second metal line operatively coupled to the metal bridge; a barrier layer surrounding the electromigration test structure; current contact pads; and voltage contact pads. The current contact pads are connected to a current source and the voltage contact pads are connected to a voltage source. The barrier layer is exposed to the elevated current density as current travels from the first metal line across the barrier layer through the metal bridge to the second metal line.

Abstract: The present invention provides methods and systems for discretized, combinatorial processing of regions of a substrate such as for the discovery, implementation, optimization, and qualification of new materials, processes, and process sequence integration schemes used in integrated circuit fabrication. A substrate having an array of differentially processed regions thereon is processed by delivering materials to or modifying regions of the substrate.

Abstract: Nonvolatile memory elements that are based on resistive switching memory element layers are provided. A nonvolatile memory element may have a resistive switching metal oxide layer. The resistive switching metal oxide layer may have one or more layers of oxide. A resistive switching metal oxide may be doped with a dopant that increases its melting temperature and enhances its thermal stability. Layers may be formed to enhance the thermal stability of the nonvolatile memory element. An electrode for a nonvolatile memory element may contain a conductive layer and a buffer layer.

Abstract: According to various embodiments, a resistive-switching memory element and memory element array that uses a bipolar switching includes a select element comprising only a single diode that is not a Zener diode. The resistive-switching memory elements described herein can switch even when a switching voltage less than the breakdown voltage of the diode is applied in the reverse-bias direction of the diode. The memory elements are able to switch during the very brief period when a transient pulse voltage is visible to the memory element, and therefore can use a single diode per memory cell.

Abstract: Methods and apparatus for processing using a remote plasma source are disclosed. The apparatus includes an outer chamber, a remote plasma source, and a showerhead. Inert gas ports within the showerhead assembly can be used to alter the concentration and energy of reactive radical or reactive neutral species generated by the remote plasma source in different regions of the showerhead. This allows the showerhead to be used to apply a surface treatment to different regions of the surface of a substrate. Varying parameters such as the remote plasma parameters, the inert gas flows, pressure, and the like allow different regions of the substrate to be treated in a combinatorial manner.

Abstract: Non-volatile resistive-switching memories formed using anodization are described. A method for forming a resistive-switching memory element using anodization includes forming a metal containing layer, anodizing the metal containing layer at least partially to form a resistive switching metal oxide, and forming a first electrode over the resistive switching metal oxide. In some examples, an unanodized portion of the metal containing layer may be a second electrode of the memory element.

Abstract: Provided are semiconductor devices, such as resistive random access memory (ReRAM) cells, that include current limiting layers formed from alloys of transition metals. Some examples of such alloys include chromium containing alloys that may also include nickel, aluminum, and/or silicon. Other examples include tantalum and/or titanium containing alloys that may also include a combination of silicon and carbon or a combination of aluminum and nitrogen. These current limiting layers may have resistivities of at least about 1 Ohm-cm. This resistivity level is maintained even when the layers are subjected to strong electrical fields and/or high temperature processing. In some embodiments, the breakdown voltage of a current limiting layer is at least about 8V. The high resistivity of the layers allows scaling down the size of the semiconductor devices including these layers while maintaining their performance.

Abstract: A system for processing a semiconductor substrate is provided. The system includes a mainframe having a plurality of modules attached thereto. The modules include processing modules, storage modules, and transport mechanisms. The processing modules may include combinatorial processing modules and conventional processing modules, such as surface preparation, thermal treatment, etch and deposition modules. In one embodiment, at least one of the modules stores multiple masks. The multiple masks enable in-situ variation of spatial location and geometry across a sequence of processes and/or multiple layers of a substrate to be processed in another one of the modules. A method for processing a substrate is also provided.