Global ETD Search

1	Reduction of Copper Oxide by Formic Acid / Eine ab-initio Studie zur Kupferoxid-Reduktion durch Ameisensäure Schmeißer, Martin 24 November 2011 (has links) (PDF) Four cluster models for a copper(I)oxide (111) surface have been designed, of which three were studied with respect to their applicability in density functional calculations in the general gradient approximation. Formic acid adsorption on these systems was modelled and yielded four different adsorption structures, of which two were found to have a high adsorption energy. The energetically most favourable adsorption structure was further investigated with respect to its decomposition and a few reactions with adsorbed H and OH species using synchronous transit methods to estimate reaction barriers and single point energy calculations for the reaction energy. Reduktion Kupferoxid CuO Cu2O Ameisensäure HCOOH ab-initio DFT Dichtefunktionaltheorie bachelor reduction copper oxide CuO Cu2O formic acid HCOOH ab-initio DFT density functional theory bachelor ddc:539 ddc:541 Reduktion <Chemie> Kupferoxide Ameisensäure Ab-initio-Rechnung Dichtefunktionalformalismus Bachelor
2	Reduction of Copper Oxide by Formic Acid: an ab-initio study Schmeißer, Martin 29 September 2011 (has links) Four cluster models for a copper(I)oxide (111) surface have been designed, of which three were studied with respect to their applicability in density functional calculations in the general gradient approximation. Formic acid adsorption on these systems was modelled and yielded four different adsorption structures, of which two were found to have a high adsorption energy. The energetically most favourable adsorption structure was further investigated with respect to its decomposition and a few reactions with adsorbed H and OH species using synchronous transit methods to estimate reaction barriers and single point energy calculations for the reaction energy.:1 Introduction 1.1 Preliminary Work 1.2 Known Reactions and Issues 1.3 Overview of Reactions and Species involved in Formic Acid Decomposition 2 Theoretical Background 2.1 The Schrödinger-Equation 2.2 Density Functional Theory 2.3 Exchange-Correlation Functionals 2.4 The Self-Consistent-Field Procedure 2.5 Geometry Optimization and Transition State Searches 2.6 Kinetics 3 Computational Details 3.1 Synchronous Transit Schemes 3.2 Transition State Searches using Eigenvector Following 4 Model System 5 Results and Discussion 5.1 Geometry of the Cu2O cluster structures 5.2 Adsorption of formic acid 5.3 Decomposition and Reaction Paths 5.3.1 Vibrational Analysis of the adsorbed Formic Acid Molecule 5.3.2 Reaction Modelling using Linear Synchronous Transit 5.3.3 Transition State Searches using Eigenvector Following 6 Summary and Outlook info:eu-repo/classification/ddc/539 ddc:539 info:eu-repo/classification/ddc/541 ddc:541
3	ALD of Copper and Copper Oxide Thin Films For Applications in Metallization Systems of ULSI Devices Waechtler, Thomas, Oswald, Steffen, Roth, Nina, Lang, Heinrich, Schulz, Stefan E., Gessner, Thomas 15 July 2008 (has links) (PDF) <p> As a possible alternative for growing seed layers required for electrochemical Cu deposition of metallization systems in ULSI circuits, the atomic layer deposition (ALD) of Cu is under consideration. To avoid drawbacks related to plasma-enhanced ALD (PEALD), thermal growth of Cu has been proposed by two-step processes forming copper oxide films by ALD which are subsequently reduced. </p> <p> This talk, given at the 8th International Conference on Atomic Layer Deposition (ALD 2008), held in Bruges, Belgium from 29 June to 2 July 2008, summarizes the results of thermal ALD experiments from [(<sup><i>n</i></sup>Bu<sub>3</sub>P)<sub>2</sub>Cu(acac)] precursor and wet O<sub>2</sub>. The precursor is of particular interest as it is a liquid at room temperature and thus easier to handle than frequently utilized solids such as Cu(acac)<sub>2</sub>, Cu(hfac)<sub>2</sub> or Cu(thd)<sub>2</sub>. Furthermore the substance is non-fluorinated, which helps avoiding a major source of adhesion issues repeatedly observed in Cu CVD. </p> <p> As result of the ALD experiments, we obtained composites of metallic and oxidized Cu on Ta and TaN, which was determined by angle-resolved XPS analyses. While smooth, adherent films were grown on TaN in an ALD window up to about 130°C, cluster-formation due to self-decomposition of the precursor was observed on Ta. We also recognized a considerable dependency of the growth on the degree of nitridation of the TaN. In contrast, smooth films could be grown up to 130°C on SiO<sub>2</sub> and Ru, although in the latter case the ALD window only extends to about 120°C. To apply the ALD films as seed layers in subsequent electroplating processes, several reduction processes are under investigation. Thermal and plasma-assisted hydrogen treatments are studied, as well as thermal treatments in vapors of isopropanol, formic acid, and aldehydes. So far these attempts were most promising using formic acid at temperatures between 100 and 120°C, also offering the benefit of avoiding agglomeration of the very thin ALD films on Ta and TaN. In this respect, the process sequence shows potential for depositing ultra-thin, smooth Cu films at temperatures below 150°C. </p> ALD Atomic Layer Deposition Atomlagenabscheidung ddc:540 ddc:620 ddc:660 Ameisensäure Dampfdruck Integrierte Schaltung Kupfer Kupferoxide Metallisieren Metallisierungsschicht Metallorganische Verbindungen Ruthenium Röntgen-Photoelektronenspektroskopie Sauerstoff Silicium Siliciumdioxid Tantal Tantalnitride ULSI Verkupferung Wasserdampf
4	Die pleiotrope Maturation der sauerstofftoleranten [NiFe]-Hydrogenasen aus Ralstonia eutropha Bürstel, Ingmar 06 May 2013 (has links) Hydrogenasen sind komplexe Enzyme, die die reversible Oxidation von molekularem Wasserstoff zu Protonen und Elektronen katalysieren. Diese Enzyme erlauben ihrem Wirtsorganismus das Wachstum unter chemolithoautotrophen Bedingungen. Der Modellorganismus Ralstonia eutropha besitzt drei gut charakterisierte Hydrogenasen der [NiFe]-Klasse, die sich durch ihre Sauerstofftoleranz auszeichnen. Ihr aktives Zentrum besteht aus einer komplexen prosthetischen Gruppe, welche aus einem Nickel- und einem Eisenatom besteht. Letzteres koordiniert drei diatomare Liganden, zwei Cyanide und ein CO. Die Synthese der gesamten Ni(SR)2(µ-SR)2Fe(CN)2(CO)-Gruppe ist ein komplexer Prozess. Die sogenannte Maturation benötigt wenigstens sechs akzessorische Proteine, die sogenannten Hyp-Proteine. Das umfassende Verständnis dieser Maturationsprozesse ermöglicht eine Vielzahl von biotechnologischen Anwendungen. Die vorliegende Arbeit untersucht die Maturation unter verschiedenen Gesichtspunkten. Zentrale, offene Fragen sind die Herkunft des Carbonylliganden sowie die Prozesse, die zur Ligandierung des katalytischen Eisens führen. Dazu wurden molekularbiologische, biochemische und spektroskopische Methoden in Verbindung mit Isotopenmarkierung eingesetzt. Unter anderem konnte dabei gezeigt werden, dass das katalytische Eisen alle seine Liganden bereits im HypCD-Komplex, dem zentralen Element der Maturation, erhält. Ferner konnte in dieser Arbeit, erstmalig für [NiFe]-Hydrogenasen, eine konkrete Biosynthese des seltenen und toxischen diatomaren CO-Liganden beschrieben werden. Ausgehend vom Alpha-Kohlenstoff von Glycin wird der Tetrahydrofolat (THF)-abhängige C1-Metabolismus mit C1-Einheiten versorgt. Durch die enzymatische Aktivität von HypX wird die Formylgruppe von N10-Formyl-THF zu CO umgesetzt. / Hydrogenases are complex enzymes that catalyze the reversible oxidation of molecular hydrogen into protons and electrons. These enzymes allow their host organism to grow under chemolithoautotrophic conditions. The model organism Ralstonia eutropha has three well-characterized [NiFe]-hydrogenases, which exhibit an extraordinary high oxygen tolerance. Its active center is a complex prosthetic group which consists of a nickel and iron atom. The latter coordinates three diatomic ligands, two cyanides and one CO. The biosynthesis of the whole Ni(SR)2(μ-SR)2Fe(CN)2(CO)-group is a complex process. This so-called maturation process needs the activity of at least six accessory proteins, the Hyp-proteins. Understanding the maturation allows a variety of biotechnological applications. The present study examines the maturation of [NiFe]-hydrogenases under different aspects. The major questions concern the origin of the carbonyl ligand as well as the processes that lead to ligandation of the designated catalytic iron. To adress these tasks, molecular biological, biochemical and spectroscopic methods in combination with isotopic labeling were employed. Inter alia, it could be shown that the catalytic iron in the HypCD-complex, the central element of the maturation process, contains all three diatomic ligands. Furthermore, this study describes, for the first time in [NiFe]-hydrogenases, a specific biosynthetic route of the rare and toxic diatomic CO-ligand. Starting from the alpha-carbon of glycine the tetrahydrofolate (THF)-dependent one-carbon metabolism is replenished with one-carbon units. Subsequently the formyl group from N10-formyl-THF is hydrolyzed by the enzymatic activity from HypX and further converted to carbon monoxide as determined by isotopic labeling and infrared spectroscopy. Kohlenmonoxid Hydrogenase Ralstonia eutropha Sauerstofftoleranz Maturation Diatomare Liganden Aktives Zentrum Tetrahydrofolat C1-Metabolismus Ameisensäure Carbonylligand CO-Ligand HypC HypD HypX maturation carbon monoxide Hydrogenase oxygen tolerance Ralstonia eutropha diatomic ligands active site tetrahydrofolate one-carbon metabolism formic acid carbonyl ligand CO-ligand HypC HypD HypX 570 Biowissenschaften, Biologie 32 Biologie WD 5055 ddc:570
5	Thermal ALD of Cu via Reduction of CuxO films for the Advanced Metallization in Spintronic and ULSI Interconnect Systems Mueller, Steve, Waechtler, Thomas, Hofmann, Lutz, Tuchscherer, Andre, Mothes, Robert, Gordan, Ovidiu, Lehmann, Daniel, Haidu, Francisc, Ogiewa, Marcel, Gerlich, Lukas, Ding, Shao-Feng, Schulz, Stefan E., Gessner, Thomas, Lang, Heinrich, Zahn, Dietrich R.T., Qu, Xin-Ping 21 February 2012 (has links) (PDF) In this work, an approach for copper atomic layer deposition (ALD) via reduction of CuxO films was investigated regarding applications in ULSI interconnects, like Cu seed layers directly grown on diffusion barriers (e. g. TaN) or possible liner materials (e. g. Ru or Ni) as well as non-ferromagnetic spacer layers between ferromagnetic films in GMR sensor elements, like Ni or Co. The thermal CuxO ALD process is based on the Cu (I) β-diketonate precursor [(nBu3P)2Cu(acac)] and a mixture of water vapor and oxygen ("wet O2") as co-reactant at temperatures between 100 and 130 °C. Highly efficient conversions of the CuxO to metallic Cu films are realized by a vapor phase treatment with formic acid (HCOOH), especially on Ru substrates. Electrochemical deposition (ECD) experiments on Cu ALD seed / Ru liner stacks in typical interconnect patterns are showing nearly perfectly filling behavior. For improving the HCOOH reduction on arbitrary substrates, a catalytic amount of Ru was successful introduced into the CuxO films during the ALD with a precursor mixture of the Cu (I) β-diketonate and an organometallic Ru precursor. Furthermore, molecular and atomic hydrogen were studied as promising alternative reducing agents. Atomlagenabscheidung ALD Ruthenium Ameisensäure Wasserstoff Reduktion ULSI Metallisierung Galvanik Spintronik Atomic Layer Deposition ALD Copper Oxide Ruthenium Formic Acid Hydrogen Reduction ULSI Interconnect Electrochemical deposition ECD Spintronics ddc:600 ddc:620 ddc:621 ddc:667 Atomlagenabscheidung Kupferoxid Ruthenium Metallisieren Galvanische Beschichtung Kupfer
6	Thin Films of Copper Oxide and Copper Grown by Atomic Layer Deposition for Applications in Metallization Systems of Microelectronic Devices Wächtler, Thomas 02 June 2010 (has links) (PDF) Copper-based multi-level metallization systems in today’s ultralarge-scale integrated electronic circuits require the fabrication of diffusion barriers and conductive seed layers for the electrochemical metal deposition. Such films of only several nanometers in thickness have to be deposited void-free and conformal in patterned dielectrics. The envisaged further reduction of the geometric dimensions of the interconnect system calls for coating techniques that circumvent the drawbacks of the well-established physical vapor deposition. The atomic layer deposition method (ALD) allows depositing films on the nanometer scale conformally both on three-dimensional objects as well as on large-area substrates. The present work therefore is concerned with the development of an ALD process to grow copper oxide films based on the metal-organic precursor bis(tri-n-butylphosphane)copper(I)acetylacetonate [(nBu3P)2Cu(acac)]. This liquid, non-fluorinated β-diketonate is brought to react with a mixture of water vapor and oxygen at temperatures from 100 to 160°C. Typical ALD-like growth behavior arises between 100 and 130°C, depending on the respective substrate used. On tantalum nitride and silicon dioxide substrates, smooth films and self-saturating film growth, typical for ALD, are obtained. On ruthenium substrates, positive deposition results are obtained as well. However, a considerable intermixing of the ALD copper oxide with the underlying films takes place. Tantalum substrates lead to a fast self-decomposition of the copper precursor. As a consequence, isolated nuclei or larger particles are always obtained together with continuous films. The copper oxide films grown by ALD can be reduced to copper by vapor-phase processes. If formic acid is used as the reducing agent, these processes can already be carried out at similar temperatures as the ALD, so that agglomeration of the films is largely avoided. Also for an integration with subsequent electrochemical copper deposition, the combination of ALD copper and ruthenium proves advantageous, especially with respect to the quality of the electroplated films and their filling behavior in interconnect structures. Furthermore, the ALD process developed also bears potential for an integration with carbon nanotubes. / Kupferbasierte Mehrlagenmetallisierungssysteme in heutigen hochintegrierten elektronischen Schaltkreisen erfordern die Herstellung von Diffusionsbarrieren und leitfähigen Keimschichten für die galvanische Metallabscheidung. Diese Schichten von nur wenigen Nanometern Dicke müssen konform und fehlerfrei in strukturierten Dielektrika abgeschieden werden. Die sich abzeichnende weitere Verkleinerung der geometrischen Dimensionen des Leitbahnsystems erfordert Beschichtungstechnologien, die vorhandene Nachteile der bisher etablierten Physikalischen Dampfphasenabscheidung beheben. Die Methode der Atomlagenabscheidung (ALD) ermöglicht es, Schichten im Nanometerbereich sowohl auf dreidimensional strukturierten Objekten als auch auf großflächigen Substraten gleichmäßig herzustellen. Die vorliegende Arbeit befasst sich daher mit der Entwicklung eines ALD-Prozesses zur Abscheidung von Kupferoxidschichten, ausgehend von der metallorganischen Vorstufe Bis(tri-n-butylphosphan)kupfer(I)acetylacetonat [(nBu3P)2Cu(acac)]. Dieses flüssige, nichtfluorierte β-Diketonat wird bei Temperaturen zwischen 100 und 160°C mit einer Mischung aus Wasserdampf und Sauerstoff zur Reaktion gebracht. ALD-typisches Schichtwachstum stellt sich in Abhängigkeit des gewählten Substrats zwischen 100 und 130°C ein. Auf Tantalnitrid- und Siliziumdioxidsubstraten werden dabei sehr glatte Schichten bei gesättigtem Wachstumsverhalten erhalten. Auch auf Rutheniumsubstraten werden gute Abscheideergebnisse erzielt, jedoch kommt es hier zu einer merklichen Durchmischung des ALD-Kupferoxids mit dem Untergrund. Tantalsubstrate führen zu einer schnellen Selbstzersetzung des Kupferprecursors, in dessen Folge neben geschlossenen Schichten während der ALD auch immer isolierte Keime oder größere Partikel erhalten werden. Die mittels ALD gewachsenen Kupferoxidschichten können in Gasphasenprozessen zu Kupfer reduziert werden. Wird Ameisensäure als Reduktionsmittel genutzt, können diese Prozesse bereits bei ähnlichen Temperaturen wie die ALD durchgeführt werden, so dass Agglomeration der Schichten weitgehend verhindert wird. Als besonders vorteilhaft für die Ameisensäure-Reduktion erweisen sich Rutheniumsubstrate. Auch für eine Integration mit nachfolgenden Galvanikprozessen zur Abscheidung von Kupfer zeigen sich Vorteile der Kombination ALD-Kupfer/Ruthenium, insbesondere hinsichtlich der Qualität der erhaltenen galvanischen Schichten und deren Füllverhalten in Leitbahnstrukturen. Der entwickelte ALD-Prozess besitzt darüber hinaus Potential zur Integration mit Kohlenstoffnanoröhren. ALD Atomic Layer Deposition Atomlagenabscheidung Beta-Diketonate Copper Copper Oxide Electroplating Formic Acid Metallization Precursor Reduction Tantalum Tantalum Nitride Vorstufe ddc:620 ddc:540 ddc:530 Ameisensäure Atomschichtepitaxie Ausgangsmaterial Diketonate <beta> Galvanische Abscheidung Kupfer Kupferoxide Metallisierungsschicht Reduktion Ruthenium Tantal Tantalnitride ULSI
7	Thin Films of Copper Oxide and Copper Grown by Atomic Layer Deposition for Applications in Metallization Systems of Microelectronic Devices Wächtler, Thomas 25 May 2010 (has links) Copper-based multi-level metallization systems in today’s ultralarge-scale integrated electronic circuits require the fabrication of diffusion barriers and conductive seed layers for the electrochemical metal deposition. Such films of only several nanometers in thickness have to be deposited void-free and conformal in patterned dielectrics. The envisaged further reduction of the geometric dimensions of the interconnect system calls for coating techniques that circumvent the drawbacks of the well-established physical vapor deposition. The atomic layer deposition method (ALD) allows depositing films on the nanometer scale conformally both on three-dimensional objects as well as on large-area substrates. The present work therefore is concerned with the development of an ALD process to grow copper oxide films based on the metal-organic precursor bis(tri-n-butylphosphane)copper(I)acetylacetonate [(nBu3P)2Cu(acac)]. This liquid, non-fluorinated β-diketonate is brought to react with a mixture of water vapor and oxygen at temperatures from 100 to 160°C. Typical ALD-like growth behavior arises between 100 and 130°C, depending on the respective substrate used. On tantalum nitride and silicon dioxide substrates, smooth films and self-saturating film growth, typical for ALD, are obtained. On ruthenium substrates, positive deposition results are obtained as well. However, a considerable intermixing of the ALD copper oxide with the underlying films takes place. Tantalum substrates lead to a fast self-decomposition of the copper precursor. As a consequence, isolated nuclei or larger particles are always obtained together with continuous films. The copper oxide films grown by ALD can be reduced to copper by vapor-phase processes. If formic acid is used as the reducing agent, these processes can already be carried out at similar temperatures as the ALD, so that agglomeration of the films is largely avoided. Also for an integration with subsequent electrochemical copper deposition, the combination of ALD copper and ruthenium proves advantageous, especially with respect to the quality of the electroplated films and their filling behavior in interconnect structures. Furthermore, the ALD process developed also bears potential for an integration with carbon nanotubes. / Kupferbasierte Mehrlagenmetallisierungssysteme in heutigen hochintegrierten elektronischen Schaltkreisen erfordern die Herstellung von Diffusionsbarrieren und leitfähigen Keimschichten für die galvanische Metallabscheidung. Diese Schichten von nur wenigen Nanometern Dicke müssen konform und fehlerfrei in strukturierten Dielektrika abgeschieden werden. Die sich abzeichnende weitere Verkleinerung der geometrischen Dimensionen des Leitbahnsystems erfordert Beschichtungstechnologien, die vorhandene Nachteile der bisher etablierten Physikalischen Dampfphasenabscheidung beheben. Die Methode der Atomlagenabscheidung (ALD) ermöglicht es, Schichten im Nanometerbereich sowohl auf dreidimensional strukturierten Objekten als auch auf großflächigen Substraten gleichmäßig herzustellen. Die vorliegende Arbeit befasst sich daher mit der Entwicklung eines ALD-Prozesses zur Abscheidung von Kupferoxidschichten, ausgehend von der metallorganischen Vorstufe Bis(tri-n-butylphosphan)kupfer(I)acetylacetonat [(nBu3P)2Cu(acac)]. Dieses flüssige, nichtfluorierte β-Diketonat wird bei Temperaturen zwischen 100 und 160°C mit einer Mischung aus Wasserdampf und Sauerstoff zur Reaktion gebracht. ALD-typisches Schichtwachstum stellt sich in Abhängigkeit des gewählten Substrats zwischen 100 und 130°C ein. Auf Tantalnitrid- und Siliziumdioxidsubstraten werden dabei sehr glatte Schichten bei gesättigtem Wachstumsverhalten erhalten. Auch auf Rutheniumsubstraten werden gute Abscheideergebnisse erzielt, jedoch kommt es hier zu einer merklichen Durchmischung des ALD-Kupferoxids mit dem Untergrund. Tantalsubstrate führen zu einer schnellen Selbstzersetzung des Kupferprecursors, in dessen Folge neben geschlossenen Schichten während der ALD auch immer isolierte Keime oder größere Partikel erhalten werden. Die mittels ALD gewachsenen Kupferoxidschichten können in Gasphasenprozessen zu Kupfer reduziert werden. Wird Ameisensäure als Reduktionsmittel genutzt, können diese Prozesse bereits bei ähnlichen Temperaturen wie die ALD durchgeführt werden, so dass Agglomeration der Schichten weitgehend verhindert wird. Als besonders vorteilhaft für die Ameisensäure-Reduktion erweisen sich Rutheniumsubstrate. Auch für eine Integration mit nachfolgenden Galvanikprozessen zur Abscheidung von Kupfer zeigen sich Vorteile der Kombination ALD-Kupfer/Ruthenium, insbesondere hinsichtlich der Qualität der erhaltenen galvanischen Schichten und deren Füllverhalten in Leitbahnstrukturen. Der entwickelte ALD-Prozess besitzt darüber hinaus Potential zur Integration mit Kohlenstoffnanoröhren. info:eu-repo/classification/ddc/620 ddc:620 info:eu-repo/classification/ddc/540 ddc:540 info:eu-repo/classification/ddc/530 ddc:530 ALD Atomic Layer Deposition Atomlagenabscheidung Beta-Diketonate Copper Copper Oxide Electroplating Formic Acid Metallization Precursor Reduction Tantalum Tantalum Nitride Vorstufe
8	Thermal ALD of Cu via Reduction of CuxO films for the Advanced Metallization in Spintronic and ULSI Interconnect Systems Mueller, Steve, Waechtler, Thomas, Hofmann, Lutz, Tuchscherer, Andre, Mothes, Robert, Gordan, Ovidiu, Lehmann, Daniel, Haidu, Francisc, Ogiewa, Marcel, Gerlich, Lukas, Ding, Shao-Feng, Schulz, Stefan E., Gessner, Thomas, Lang, Heinrich, Zahn, Dietrich R.T., Qu, Xin-Ping January 2011 (has links) In this work, an approach for copper atomic layer deposition (ALD) via reduction of CuxO films was investigated regarding applications in ULSI interconnects, like Cu seed layers directly grown on diffusion barriers (e. g. TaN) or possible liner materials (e. g. Ru or Ni) as well as non-ferromagnetic spacer layers between ferromagnetic films in GMR sensor elements, like Ni or Co. The thermal CuxO ALD process is based on the Cu (I) β-diketonate precursor [(nBu3P)2Cu(acac)] and a mixture of water vapor and oxygen ("wet O2") as co-reactant at temperatures between 100 and 130 °C. Highly efficient conversions of the CuxO to metallic Cu films are realized by a vapor phase treatment with formic acid (HCOOH), especially on Ru substrates. Electrochemical deposition (ECD) experiments on Cu ALD seed / Ru liner stacks in typical interconnect patterns are showing nearly perfectly filling behavior. For improving the HCOOH reduction on arbitrary substrates, a catalytic amount of Ru was successful introduced into the CuxO films during the ALD with a precursor mixture of the Cu (I) β-diketonate and an organometallic Ru precursor. Furthermore, molecular and atomic hydrogen were studied as promising alternative reducing agents. info:eu-repo/classification/ddc/600 ddc:600 info:eu-repo/classification/ddc/620 ddc:620 info:eu-repo/classification/ddc/621 ddc:621 info:eu-repo/classification/ddc/667 ddc:667
9	ALD of Copper and Copper Oxide Thin Films For Applications in Metallization Systems of ULSI Devices Waechtler, Thomas, Oswald, Steffen, Roth, Nina, Lang, Heinrich, Schulz, Stefan E., Gessner, Thomas 15 July 2008 (has links) As a possible alternative for growing seed layers required for electrochemical Cu deposition of metallization systems in ULSI circuits, the atomic layer deposition (ALD) of Cu is under consideration. To avoid drawbacks related to plasma-enhanced ALD (PEALD), thermal growth of Cu has been proposed by two-step processes forming copper oxide films by ALD which are subsequently reduced. This talk, given at the 8th International Conference on Atomic Layer Deposition (ALD 2008), held in Bruges, Belgium from 29 June to 2 July 2008, summarizes the results of thermal ALD experiments from [(<sup><i>n</i></sup>Bu<sub>3</sub>P)<sub>2</sub>Cu(acac)] precursor and wet O<sub>2</sub>. The precursor is of particular interest as it is a liquid at room temperature and thus easier to handle than frequently utilized solids such as Cu(acac)<sub>2</sub>, Cu(hfac)<sub>2</sub> or Cu(thd)<sub>2</sub>. Furthermore the substance is non-fluorinated, which helps avoiding a major source of adhesion issues repeatedly observed in Cu CVD. As result of the ALD experiments, we obtained composites of metallic and oxidized Cu on Ta and TaN, which was determined by angle-resolved XPS analyses. While smooth, adherent films were grown on TaN in an ALD window up to about 130°C, cluster-formation due to self-decomposition of the precursor was observed on Ta. We also recognized a considerable dependency of the growth on the degree of nitridation of the TaN. In contrast, smooth films could be grown up to 130°C on SiO<sub>2</sub>and Ru, although in the latter case the ALD window only extends to about 120°C. To apply the ALD films as seed layers in subsequent electroplating processes, several reduction processes are under investigation. Thermal and plasma-assisted hydrogen treatments are studied, as well as thermal treatments in vapors of isopropanol, formic acid, and aldehydes. So far these attempts were most promising using formic acid at temperatures between 100 and 120°C, also offering the benefit of avoiding agglomeration of the very thin ALD films on Ta and TaN. In this respect, the process sequence shows potential for depositing ultra-thin, smooth Cu films at temperatures below 150°C. ALD Atomic Layer Deposition Atomlagenabscheidung info:eu-repo/classification/ddc/540 ddc:540 info:eu-repo/classification/ddc/620 ddc:620 info:eu-repo/classification/ddc/660 ddc:660 Ameisensäure Dampfdruck Integrierte Schaltung Kupfer Kupferoxide Metallisieren Metallisierungsschicht Metallorganische Verbindungen Ruthenium Röntgen-Photoelektronenspektroskopie Sauerstoff Silicium Siliciumdioxid Tantal Tantalnitride ULSI Verkupferung Wasserdampf

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