Abstract: This invention includes methods of forming patterned photoresist layers over semiconductor substrates. In one implementation, a porous antireflective coating is formed over a semiconductor substrate. A photoresist footer-reducing fluid is provided within pores of the porous antireflective coating. A positive photoresist is formed over the porous antireflective coating having the fluid therein. The positive photoresist is patterned and developed to form a patterned photoresist layer, with the fluid within the pores being effective to reduce photoresist footing in the patterned photoresist layer than would otherwise occur in the absence of the fluid within the pores. Other aspects and implementations are contemplated.

Abstract: A plasma probe system includes a plasma probe, at least one meter, and a diagnostic apparatus. The probe may include a substrate having substantially the same properties as those of a substrate to be processed, a bottom electrode layer located over the substrate and electrically isolated therefrom, a dielectric layer positioned over the bottom electrode layer including apertures through which one or more electrodes of the bottom electrode layer are exposed, and at least one upper electrode layer that is electrically isolated from the bottom electrode layer by way of the dielectric layer. Electrodes of the bottom and upper electrode layers communicate with meters which may provide real-time data representative of one or more properties of a region of a plasma to which the electrodes are exposed.

Abstract: A first precursor gas is flowed to the substrate within the chamber effective to form a first monolayer on the substrate. A second precursor gas different in composition from the first precursor gas is flowed to the first monolayer within the chamber under surface microwave plasma conditions within the chamber effective to react with the first monolayer and form a second monolayer on the substrate which is different in composition from the first monolayer. The second monolayer includes components of the first monolayer and the second precursor. In one implementation, the first and second precursor flowings are successively repeated effective to form a mass of material on the substrate of the second monolayer composition. Additional and other implementations are contemplated.

Abstract: A method of forming a reaction product includes providing a semiconductor substrate comprising a first material. A second material is formed over the first material. The first and second materials are of different compositions, and are proximate one another at an interface. The first and second materials as being proximate one another at the interface are capable of reacting with one another at some minimum reaction temperature when in an inert non-plasma atmosphere at a pressure. The interface is provided at a processing temperature which is at least 50° C. below the minimum reaction temperature, and is provided at the pressure. With the interface at the processing temperature and at the pressure, the substrate is exposed to a plasma effective to impart a reaction of the first material with the second material to form a reaction product third material of the first and second materials over the first material. Other aspects and implementations are contemplated.

Abstract: In one aspect, the invention includes a method of forming a material within an opening, comprising: a) forming an etch-stop layer over a substrate, the etch-stop layer having an opening extending therethrough to expose a portion of the underlying substrate and comprising an upper corner at a periphery of the opening, the upper corner having a corner angle with a first degree of sharpness; b) reducing the sharpness of the corner angle to a second degree; c) after reducing the sharpness, forming a layer of material within the opening and over the etch-stop layer; and d) planarizing the material with a method selective for the material relative to the etch-stop layer to remove the material from over the etch-stop layer while leaving the material within the opening.

Abstract: The invention encompasses methods of forming insulating materials between conductive elements. In one aspect, the invention includes a method of forming a material adjacent a conductive electrical component comprising: a) partially vaporizing a mass to form a matrix adjacent the conductive electrical component, the matrix having at least one void within it. In another aspect, the invention includes a method of forming a material between a pair of conductive electrical components comprising the following steps: a) forming a pair of conductive electrical components within a mass and separated by an expanse of the mass; b) forming at least one support member within the expanse of the mass, the support member not comprising a conductive interconnect; and c) vaporizing the expanse of the mass to a degree effective to form at least one void between the support member and each of the pair of conductive electrical components.

Abstract: Methods and apparatus are described to facilitate forming memory devices with low resistance polysilicon local interconnects that allow a smaller array feature size and therefore facilitate forming arrays of a denser array format. Embodiments of the present invention are formed utilizing a wet etch process that has a high selectivity, allowing the deposition and etching of polysilicon local interconnects to source regions of array transistors. By providing for a local interconnect of polysilicon, a smaller source region and/or drain region can also be utilized, further decreasing the required word line spacing. Low resistance polysilicon local source interconnects can also couple to an increased number of memory cells, thereby reducing the number of contacts made to an array ground.

Abstract: Sensors and methods of monitoring for the presence of gas phase materials by detecting the formation of films based on the gas phase material are disclosed. Advantageously, some gas phase materials preferentially deposit on specific surfaces. As a result, selective detection of those gas phase materials can be obtained by detecting films deposited on those detection surfaces. Examples of gas phase materials that may be detected include RuO4, IrO4 and RhO4.

Abstract: A plasma probe that includes a substrate having substantially the same properties as those of a substrate to be processed, a bottom electrode layer located over the substrate and electrically isolated therefrom, a dielectric layer positioned over the bottom electrode layer including apertures through which one or more electrodes of the bottom electrode layer are exposed, and at least one upper electrode layer that is electrically isolated from the bottom electrode layer by way of the dielectric layer. Electrodes of the bottom and upper electrode layers communicate with meters which may provide real-time data representative of one or more properties of a region of a plasma to which the electrodes are exposed. The plasma probe may be fabricated by forming the bottom electrode layer over the substrate and separately forming one or more upper electrode layers over a sacrificial substrate. These structures are assembled with the dielectric layer therebetween.

Abstract: The invention encompasses a method of forming a rugged silicon-containing surface. A layer comprising amorphous silicon is provided within a reaction chamber at a first temperature. The temperature is increased to a second temperature at least 40° C. higher than the first temperature while flowing at least one hydrogen isotope into the chamber. After the temperature reaches the second temperature, the layer is seeded with seed crystals. The seeded layer is then annealed to form a rugged silicon-containing surface. The rugged silicon-containing surface can be incorporated into a capacitor construction. The capacitor construction can be incorporated into a DRAM cell, and the DRAM cell can be utilized in an electronic system.

Abstract: The invention encompasses a method of forming a rugged silicon-containing surface. A layer comprising amorphous silicon is provided within a reaction chamber at a first temperature. The temperature is increased to a second temperature at least 40° C. higher than the first temperature while flowing at least one hydrogen isotope into the chamber. After the temperature reaches the second temperature, the layer is seeded with seed crystals. The seeded layer is then annealed to form a rugged silicon-containing surface. The rugged silicon-containing surface can be incorporated into a capacitor construction. The capacitor construction can be incorporated into a DRAM cell, and the DRAM cell can be utilized in an electronic system.

Abstract: The invention includes a method of forming a rugged semiconductor-containing surface. A first semiconductor layer is formed over a substrate, and a second semiconductor layer is formed over the first semiconductor layer. Subsequently, a third semiconductor layer is formed over the second semiconductor layer, and semiconductor-containing seeds are formed over the third semiconductor layer. The seeds are annealed to form the rugged semiconductor-containing surface. The first, second and third semiconductor layers are part of a common stack, and can be together utilized within a storage node of a capacitor construction. The invention also includes semiconductor structures comprising rugged surfaces. The rugged surfaces can be, for example, rugged silicon.

Abstract: The invention encompasses methods of forming insulating materials between conductive elements. In one aspect, the invention includes a method of forming a material adjacent a conductive electrical component comprising: a) partially vaporizing a mass to form a matrix adjacent the conductive electrical component, the matrix having at least one void within it. In another aspect, the invention includes a method of forming a material between a pair of conductive electrical components comprising the following steps: a) forming a pair of conductive electrical components within a mass and separated by an expanse of the mass; b) forming at least one support member within the expanse of the mass, the support member not comprising a conductive interconnect; and c) vaporizing the expanse of the mass to a degree effective to form at least one void between the support member and each of the pair of conductive electrical components.

Abstract: Resistive heaters formed in two mask counts on a surface of a grating of a thermo optic device thereby eliminating one mask count from prior art manufacturing methods. The resistive heater is comprised of a heater region and a conductive path region formed together in a first mask count from a relatively high resistance material. A conductor formed from a relatively low resistance material is formed directly on the conductive path region in a second mask count. Thermo optic devices formed by these two mask count methods are also described.

Abstract: A waveguide and resonator are formed on a lower cladding of a thermo optic device, each having a formation height that is substantially equal. Thereafter, the formation height of the waveguide is attenuated. In this manner, the aspect ratio as between the waveguide and resonator in an area where the waveguide and resonator front or face one another decreases (in comparison to the prior art) thereby restoring the synchronicity between the waveguide and the grating and allowing higher bandwidth configurations to be used. The waveguide attenuation is achieved by photomasking and etching the waveguide after the resonator and waveguide are formed. In one embodiment the photomasking and etching is performed after deposition of the upper cladding. In another, it is performed before the deposition. Thermo optic devices, thermo optic packages and fiber optic systems having these waveguides are also taught.

Abstract: A plasma reactor comprises an electromagnetic energy source coupled to a radiator through first and second variable impedance networks. The plasma reactor includes a chamber having a dielectric window that is proximate to the radiator. A shield is positioned between the radiator and the dielectric window. The shield substantially covers a surface of the radiator near the dielectric window. A portion of the radiator that is not covered by the shield is proximate to a conductive wall of the chamber. Plasma reactor operation includes the following steps. A plasma is ignited in a chamber with substantially capacitive electric energy coupled from the radiator. A variable impedance network is tuned so that the capacitive electric energy coupled into the chamber is diminished. The plasma is then powered with substantially magnetic energy.

Abstract: Resistive heaters formed in two mask counts on a surface of a grating of a thermo optic device thereby eliminating one mask count from prior art manufacturing methods. The resistive heater is comprised of a heater region and a conductive path region formed together in a first mask count from a relatively high resistance material. A conductor formed from a relatively low resistance material is formed directly on the conductive path region in a second mask count. Thermo optic devices formed by these two mask count methods are also described.

Abstract: An apparatus for film deposition onto a substrate from a source of target particles including a plasma generator creating a plasma that isotropically accelerates the target particles towards the substrate. A secondary ionizer creates a secondary ionization zone between the plasma and the substrate support. The isotropically accelerated target particles are ionized as they pass through the secondary ionization zone. A static field generator creates a static field between the secondary ionization zone and the substrate accelerating the ionized target particles along a substantially collimated trajectory perpendicular to the substrate. Optionally, a collimator is included between the secondary ionization zone and the substrate and biased to focus and accelerate the collimated target particles.

Abstract: Methods of forming insulating materials between conductive elements include forming a material adjacent a conductive electrical component comprising: partially vaporizing a mass to form a matrix adjacent the conductive electrical component, the matrix having at least one void within it. Other methods include forming a material between a pair of conductive electrical components comprising: forming a pair of conductive electrical components within a mass and separated by an expanse of the mass; forming at least one support member within the expanse of the mass, the support member not comprising a conductive interconnect; and vaporizing the expanse of the mass to a degree effective to form at least one void between the support member and each of the pair of conductive electrical components. Some embodiments include an insulating material adjacent a conductive electrical component, such material comprising a matrix and at least one void within the matrix.

Abstract: A permanent protective semiconductor die coating made from a polymer that is fully curable through exposure to ultra violet light. A mixture of polymer resin and a photoactive compound is applied to the die and then cured through exposure to ultraviolet light to form the protective coating. In one preferred embodiment, the polymer resin is a phenol-formaldehyde epoxy resin and the photoactive compound is CD1011 (marketed under the brand name SARTOMER□. The coating may be applied as a thin protective film, such as a passivation layer, or as a thicker encapsulant used for semiconductor device packages. Such film coatings exhibit reduced film shrinkage and lower film stresses while maintaining mechanical properties comparable to polyimide film coatings.