Abstract: A method of cleaning a metal oxide thin film on a silicon wafer, includes dipping the wafer in an organic solvent; drying the wafer in a nitrogen atmosphere; and stripping any photoresist from the wafer in an oxygen atmosphere under partial vacuum at a temperature of about 200° C. The wafer may also be cleaned by dipping in a polar organic solvent and subjecting the wafer to ultrasound while immersed in the solvent.

Abstract: A thin film structure includes a substantially single-phase, c-axis PGO film on an insulator for use in metal ferroelectric insulator semiconductor single transistor non-volatile memory applications. The PGO on insulator structure can also be used in capacitors, pyroelectric infrared sensors, optical displays, optical switches, piezoelectric transducers, and surface acoustic wave devices. In a preferred embodiment, the PGO film is deposited on a Zirconium Oxide insulator layer.

Abstract: Methods of forming hafnium oxide, zirconium oxide and nanolaminates of hafnium oxide and zirconium oxide are provided. These methods utilize atomic layer deposition techniques incorporating nitrate-based precursors, such as hafnium nitrate and zirconium nitrate. The use of these nitrate based precursors is well suited to forming high dielectric constant materials on hydrogen passivated silicon surfaces.

Abstract: A method of preparing a PGO solution for spin coating includes preparing a 2-methoxyethanol organic solvent; adding Pb(OCH3CO)2.3H2O to the organic solvent at ambient temperature and pressure in a nitrogen-filled glaved box to form Pb in methoxyethanol; refluxing the solution in a nitrogen atmosphere at 150° C. for at least two hours; fractionally distilling the refluxed solution at approximately 150° C. to remove all of the water from the solution; cooling the solution to room temperature; determining the Pb concentration of the solution; adding the 2-methoxyethanol solution to the Pb 2-methoxyethanol until a desired Pb concentration is achieved; combining Ge(OR)4, where R is taken the group of Rs consisting of CH2CH3 and CH(CH3)2, and 2-methoxyethanol; and adding Ge(OR)4 2-methoxyethanol to PbO 2-methoxyethanol to form the PGO solution having a predetermined metal ion concentration and a predetermined Pb:Ge molar ration.

Abstract: A method of fabricating a one-transistor memory includes, on a single crystal silicon substrate, depositing a bottom electrode structure on a gate oxide layer; implanting ions to form a source region and a drain region and activating the implanted ions spin coating the structure with a first ferroelectric layer; depositing a second ferroelectric layer; and annealing the structure to provide a c-axis ferroelectric orientation.

Abstract: An Ir—M—O composite film has been provided that is useful in forming an electrode of a ferroelectric capacitor, where M includes a variety of refractory metals. The Ir combination film is resistant to high temperature annealing in oxygen environments. When used with an underlying barrier layer made from the same variety of M transition metals, the resulting conductive barrier also suppresses to diffusion of Ir into any underlying Si substrates. As a result, Ir silicide products are not formed, which degrade the electrode interface characteristics. That is, the Ir combination film remains conductive, not peeling or forming hillocks, during high temperature annealing processes, even in oxygen. The Ir—M—O conductive electrode/barrier structures are useful in nonvolatile FeRAM devices, DRAMs, capacitors, pyroelectric infrared sensors, optical displays, optical switches, piezoelectric transducers, and surface acoustic wave devices.

Abstract: A method of forming a volatile copper precursor for chemical vapor deposition of copper metal thin film includes formation of a volatile liquid having a chemical formula of (n-R-m-cyclohexene)Cu(I)(hfac) or (n-R-m-cyclopentene)Cu(I)(hfac), where n,m=1-6, and where R is a alkyl, such as methyl and ethyl.

Abstract: A Cu(hfac) precursor with a substituted phenylethylene ligand has been provided. The substituted phenylethylene ligand includes bonds to molecules selected from the group consisting of C1 to C6 alkyl, C1 to C6 haloalkyl, C1 to C6 phenyl, H and C1 to C6 alkoxyl. One variation, the &agr;-methylstyrene ligand precursor has proved to be stable a low temperatures, and sufficiently volatile at higher temperatures. Copper deposited with this precursor has low resistivity and high adhesive characteristics. A synthesis method has been provided which produces a high yield of the above-described precursor.

Abstract: A Cub(hfac) precursor with a substituted phenylethylene ligand has been provided. The substituted phenylethylene ligand includes bonds to molecules selected from the group consisting of C1 to C6 alkyl, C1 to C6 haloalkyl, C1 to C6 phenyl, H and C1 to C6 alkoxyl. One variation, the &agr;-methylstyrene ligand precursor has proved to be stable a low temperatures, and sufficiently volatile at higher temperatures. Copper deposited with this precursor has low resistivity and high adhesive characteristics. A synthesis method has been provided which produces a high yield of the above-described precursor.

Abstract: A method for using a Cu(hfac) precursor with a substituted phenylethylene ligand to form an adhesive seed layer on an IC surface has been provided. The substituted phenylethylene ligand includes bonds to molecules selected from the group consisting of C1 to C6 alkyl, C1 to C6 haloalkyl, phenyl, H and C1 to C6 alkoxyl. One variation, the &agr;-methylstyrene ligand precursor has proved to be especially adhesive. Copper deposited with this precursor has low resistivity and high adhesive characteristics. The seed layer provides a foundation for subsequent Cu layers deposited through either CVD, PVD, or electroplating. The adhesive seed layer permits the subsequent Cu layer to be deposited through an economical high deposition rate process.

Abstract: An Ir—M—O composite film has been provided that is useful in forming an electrode of a ferroelectric capacitor, where M includes a variety of refractory metals. The Ir combination film is resistant to high temperature annealing in oxygen environments. When used with an underlying barrier layer made from the same variety of M transition metals, the resulting conductive barrier also suppresses to diffusion of Ir into any underlying Si substrates. As a result, Ir silicide products are not formed, which degrade the electrode interface characteristics. That is, the Ir combination film remains conductive, not peeling or forming hillocks, during high temperature annealing processes, even in oxygen. The Ir—M—O conductive electrode/barrier structures are useful in nonvolatile FeRAM devices, DRAMs, capacitors, pyroelectric infrared sensors, optical displays, optical switches, piezoelectric transducers, and surface acoustic wave devices.

Abstract: A metal(hfac), alkene ligand precursor has been provided. The alkene ligand includes double bonded carbon atoms, with first and second bonds to the first carbon atom, and third and fourth bonds to the second carbon atom. The first, second, third, and fourth bonds are selected from a the group consisting of H, C.sub.1 to C.sub.8 alkyl, C.sub.1 to C.sub.8 haloalkyl, and C.sub.1 to C.sub.8 alkoxyl. As a general class, these precursors are capable of high metal deposition rates and high volatility, despite being stable in the liquid phase at low temperatures. Copper deposited with this precursor has low resistivity and high adhesive characteristics. A synthesis method has been provided which produces a high yield of the above-described alkene ligand class of metal precursors.

Abstract: A Cu(hfac) allyl-derived ligand precursor has been provided. The ligand includes group consisting of alkyl, phenyl, trialkylsilane, trialkoxylsilane, halodialkylsilane, dihaloalkylsilane, trihalosilane, triphenylsilane, alkoxyl, halogen, chloroformate, cynanide, cycloalkyl, cycloalkylamine, alkyl ether, isocyanate, and pentafluorobenzene. Examples of the allyl-derived ligand precursors have proved to be stable at room temperatures, and sufficiently volatile at higher temperatures. Copper deposited with this precursor has low resistivity and high adhesive characteristics. A synthesis method has been provided which produces a high yield of the above-described precursors, including a Cu(hfac)(allyltrimethylsilane) precursor.

Abstract: A Cu(hfac) precursor with a substituted ethylene ligand has been provided. The substituted ethylene ligand includes bonds to molecules selected from the group consisting of C.sub.1 to C.sub.8 alkyl, C.sub.1 to C.sub.8 haloalkyl, H, and C.sub.1 to C.sub.8 alkoxyl. One variation, the 2-methyl-1-butene ligand precursor has proved to be stable at room temperature, and extremely volatile at higher temperatures. Copper deposited with this precursor has low resistivity and high adhesive characteristics. Because of the volatility, the deposition rate of copper deposited with this precursor is very high. A synthesis method has been provided which produces a high yield of the above-described precursor.