Abstract: An embodiment of the instant invention is a method of forming a conductive barrier layer on a dielectric layer, the method comprising the steps of: providing the dielectric layer (112 of FIG. 7d) having a top surface, a bottom surface, and an opening extending from the top surface to the bottom surface, and including a conductive plug (704 of FIG.

Abstract: Plasma charging devices and methods are disclosed for detecting plasma charging during semiconductor wafer processing. Charging monitors are disclosed having ferroelectric capacitance elements which can be preprogrammed prior to processing steps of interest, and then subsequently measured afterwards, in order to determine whether plasma related charging is a problem in the intervening processing steps.

Abstract: Improved methods of forming PZT thin films that are compatible with industry-standard chemical vapor deposition production techniques are described. These methods enable PZT thin films having thicknesses of 70 nm or less to be fabricated with high within-wafer uniformity, high throughput and at a relatively low deposition temperature. In one aspect, a source reagent solution comprising a mixture of a lead precursor, a titanium precursor and a zirconium precursor in a solvent medium is provided. The source reagent solution is vaporized to form a precursor vapor. The precursor vapor is introduced into a chemical vapor deposition chamber containing the substrate. In another aspect, before deposition, the substrate is preheated during a preheating period. After the preheating period, the substrate is disposed on a heated susceptor during a heating period, after which a PZT film is formed on the heated substrate.

Abstract: An embodiment of the instant invention is a method of fabricating a ferroelectric capacitor which is situated over a structure, the method comprising the steps of: forming a bottom electrode on the structure (124 of FIG. 1), the bottom electrode having a top surface and sides; forming a capacitor dielectric (126 of FIG. 1) comprised of a ferroelectric material on the bottom electrode, the capacitor dielectric having a top surface and sides; forming a top electrode (128 and 130 of FIG. 1) on the capacitor dielectric, the top electrode having a top surface and sides, the ferroelectric capacitor is comprised of the bottom electrode, the capacitor dielectric, and the top electrode; forming a barrier layer (118 and 120 of FIG.

Abstract: A via etch to contact a capacitor with ferroelectric between electrodes together with dielectric on an insulating diffusion barrier includes two-step etch with F-based dielectric etch and Cl- and F-based barrier etch.

Abstract: An embodiment of the instant invention is a ferroelectric capacitor formed over a semiconductor substrate, the ferroelectric capacitor comprising: a bottom electrode formed over the semiconductor substrate, the bottom electrode comprised of a bottom electrode material (304 of FIG. 4a); a top electrode formed over the bottom electrode and comprised of a first electrode material (306and 308 of FIG. 4a); a ferroelectric material (306 of FIG. 4a) situated between the top electrode and the bottom electrode; and a hardmask formed on the top electrode and comprising a bottom hardmask layer (402 of FIG. 4a) and a top hardmask layer (408 of FIG.

Abstract: A method of fabricating a ferroelectric capacitor is disclosed. The method comprises the decreases a reduction in a bottom electrode material during formation of the ferroelectric dielectric portion of the capacitor. In the above manner, a fatigue resistance of the ferroelectric capacitor is increased substantially.

Abstract: A method of fabricating a ferroelectric capacitor is disclosed. The method comprises the patterning of a top electrode layer and a dielectric layer to form a capacitor stack structure having sidewalls associated therewith. Prior to patterning the bottom electrode layer, a protective film is formed on the sidewalls of the capacitor stack structure in order to protect the dielectric material from conductive contaminants associated with a subsequent patterning of the bottom electrode layer.

Abstract: A ferroelectric device fabrication process is described in which ferroelectric device contaminant substances (e.g., Pb, Zr, Ti, and Ir) that are incompatible with standard CMOS fabrication processes are tightly controlled. In particular, specific etch chemistries have been developed to remove incompatible substances from the backside and edge surfaces of the substrate after a ferroelectric device has been formed. In addition, a sacrificial layer may be disposed over the bottom and edge surfaces (and, in some embodiments, the frontside edge exclusion zone surface) of the substrate to assist in the removal of difficult-to-etch contaminants (e.g., Ir). In this way, the ferroelectric device fabrication process may be integrated with a standard semiconductor fabrication process, whereby ferroelectric devices may be formed together with semiconductor integrated circuits without substantial risk of cross-contamination through shared equipment (e.g., steppers, metrology tools, and the like).

Abstract: A method of fabricating a ferroelectric capacitor is disclosed. The method comprises the decreases a reduction in a bottom electrode material during formation of the ferroelectric dielectric portion of the capacitor. In the above manner, a fatigue resistance of the ferroelectric capacitor is increased substantially.

Abstract: A via etch to contact a capacitor with ferroelectric between electrodes together with dielectric on an insulating diffusion barrier includes two-step etch with F-based dielectric etch and Cl- and F-based barrier etch.

Abstract: A method for simultaneously producing areas of paraelectric states and areas of ferroelectric states on a single thin film layer, thereby reducing the number of processing steps required to produce integrated chips containing both standard capacitors and non-volatile memory devices from the number of steps needed using the conventional approach. A device containing both ferroelectric capacitors and non-ferroelectric capacitors using a single thin film as the dielectric.

Abstract: An embodiment of the instant invention is a method of forming a conductive barrier layer on a dielectric layer, the method comprising the steps of: providing the dielectric layer (112 of FIG. 7d) having a top surface, a bottom surface, and an opening extending from the top surface to the bottom surface, and including a conductive plug (704 of FIG.

Abstract: A via etch to contact a capacitor with ferroelectric between electrodes together with dielectric on an insulating diffusion barrier includes two-step etch with F-based dielectric etch and Cl- and F-based barrier etch.

Abstract: An embodiment of the instant invention is a method of fabricating a planar conductive via in an opening through a dielectric layer having a top surface, a bottom surface and the opening having sides, the method comprising the steps of: depositing a first conductive material (114 of FIG. 7d) on the top surface of the dielectric layer and in the opening in the dielectric layer to substantially fill the opening with the conductive material; removing the portion of the first conductive material located on the dielectric layer and removing a portion of the first conductive material located in the opening in the dielectric layer to recess (406 of FIG. 7d) the first conductive material below the top surface of the dielectric layer; depositing a second conductive material (704 of FIG. 7d) in the recess to form a substantially planar top surface substantially coplanar with the top surface of the dielectric layer; and forming a third conductive material (302 of FIG.

Abstract: An embodiment of the instant invention is a ferroelectric capacitor formed over a semiconductor substrate, the ferroelectric capacitor comprising: a bottom electrode formed over the semiconductor substrate, the bottom electrode comprised of a bottom electrode material (304 of FIG. 4a); a top electrode formed over the bottom electrode and comprised of a first electrode material (306 and 308 of FIG. 4a); a ferroelectric material (306 of FIG. 4a) situated between the top electrode and the bottom electrode; and a hardmask formed on the top electrode and comprising a bottom hardmask layer (402 of FIG. 4a) and a top hardmask layer (408 of FIG.

Abstract: A via etch to contact a capacitor with ferroelectric between electrodes together with dielectric on an insulating diffusion barrier includes two-step etch with F-based dielectric etch and Cl- and F-based barrier etch.