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| Author | : Ling Wang |
| Publisher | : |
| Total Pages | : 278 |
| Release | : 2006 |
| Genre | : |
| ISBN | : |
| Author | : Seungchoun Choi |
| Publisher | : |
| Total Pages | : 166 |
| Release | : 2013 |
| Genre | : |
| ISBN | : |
With stringent requirements of copper chemical mechanical planarization (CMP), such as minimized step heights, enhanced uniformity and minimal defects, the CMP process needs to be improved based on a fundamental understanding of the material removal mechanisms. Also, with the stringent requirements, the problems in copper CMP process cannot be resolved solely improving the process itself; rather, systemic understanding of the entire manufacturing processes is necessary, demanding a robust copper CMP model to be implemented to design for manufacturing (DfM) tools. Previous models heavily relied on Preston's equation (), which needs to be calibrated for every new set of processing parameters, slowing down the process development. Previous models focused on limited interactions of the consumables and the workpiece during copper CMP, being insufficient at capturing the synergies between chemical and mechanical aspects of copper CMP. Therefore, a quantitative and physicochemical model of copper CMP that predicts material removal rate (MRR) was proposed while focusing on the interplay of consumables and copper and the synergies between chemical and mechanical aspects of the process. While considering the synergies, two mechanisms of the material removal during copper CMP were suggested: chemically dominant and mechanically dominant mechanisms. The total MRR during copper CMP was determined by summing those two contributions. The chemically dominant mechanism attributed the material removal during copper CMP to the removal of the protective material formed on the surface of copper and to the chemical dissolution of copper from the surface both at regions occupied and not occupied by the protective material with different rates. The kinetics of the formation of the protective material at the millisecond scale were studied through electrochemical experiments and theoretical analysis where a governing equation for the adsorption of benzotriazole (BTA) was constructed and solved. It was found that the grown protective material (CuBTA) during copper CMP was only a fraction of a monolayer partly occupying the surface of a wafer. This was because the time allowed for the adsorption of BTA on the surface of copper was limited by the time between consecutive asperity and copper interactions, which was only of the order of one millisecond. The formation and the removal of the protective material were assumed to be balanced during CMP, yielding a constant chemically dominant MRR. The removal of the protective material by abrasion with abrasive particles was investigated by in situ electrochemical measurement during polishing. The removal efficiency of a pad asperity where abrasive particles are embedded was evaluated from the measurements and was compared with the theoretical analysis. It showed a good agreement and suggested that the copper during CMP is mostly deformed elastically by the abrasive particles. The influence of the concentration of copper ions on the kinetics of the formation of the protective material was also investigated using potential-step chronoamperometry using two types of copper microelectrode, namely a three dimensional and a planar electrode. The amount of copper ion may easily build up to a level that exceeds the solubility product of Cu(II)BTA2. Under these conditions, Cu(II)BTA2 can nucleate, consuming the protective material formed on the surface of copper. This phenomenon is highly undesirable as it increases the dissolution rates at the regions where the protective material is removed, worsening the topography after copper CMP. The mechanically dominant MRR was determined from the volume of a wafer that is plastically deformed by indentation of abrasives that are squeezed between pad asperities and the wafer. The shear stress induced in copper by the force applied on an abrasive is lower than the ideal shear strength of copper, which is the relevant property for plasticity at this length scale. However, the crystallographic defects in the copper crystal may reduce the hardness of the material, allowing the material to be plastically deformed. Especially the roughness of the surface induced by chemical additives in the slurry greatly reduces the resistance to plastic deformation of copper. Because of the localized spatial distribution of those crystallographic defects the plastic deformation occurs only locally. Also, only a part of the plastically deformed material will be detached from the surface, contributing to the MRR. While applying this mechanism, the discrepancy of the MRR behavior with varying size and concentration of abrasives between the prediction and the experimental observations was resolved by proposing a new mechanism that determines the number of abrasives participating in the abrasion of the material. The transport mechanisms of abrasive particles toward a wafer and the electrostatic interactions between abrasives were considered to affect the number of abrasive particles deposited on the surface of a wafer. If the deposition of abrasives on the surface of a wafer is limited by the diffusion of abrasives, the MRR decreases with the size of the abrasives. In contrast, the MRR increases with the size of abrasives if the deposition of the abrasives is limited by the jamming limit of the deposited abrasives at the surface of the wafer. Also, micrometer sized abrasives increases the MRR when the size is increased because the deposition of abrasives is limited by the interception mechanism of the abrasives. The proposed model successfully captured the synergies between chemical and mechanical aspects and quantitatively predicted the MRR during copper CMP. In the future, the model will be applied to predict the pattern dependent variability of topography of a wafer after CMP. The proposed model quantitatively predicts the local MRR of copper. Along with a robust model for dielectric and barrier materials, the model can predict the topography after CMP, contributing to the optimization of the CMP process.
| Author | : Babu Suryadevara |
| Publisher | : Woodhead Publishing |
| Total Pages | : 650 |
| Release | : 2021-09-10 |
| Genre | : Technology & Engineering |
| ISBN | : 0128218193 |
Advances in Chemical Mechanical Planarization (CMP), Second Edition provides the latest information on a mainstream process that is critical for high-volume, high-yield semiconductor manufacturing, and even more so as device dimensions continue to shrink. The second edition includes the recent advances of CMP and its emerging materials, methods, and applications, including coverage of post-CMP cleaning challenges and tribology of CMP. This important book offers a systematic review of fundamentals and advances in the area. Part one covers CMP of dielectric and metal films, with chapters focusing on the use of current and emerging techniques and processes and on CMP of various materials, including ultra low-k materials and high-mobility channel materials, and ending with a chapter reviewing the environmental impacts of CMP processes. New content addressed includes CMP challenges with tungsten, cobalt, and ruthenium as interconnect and barrier films, consumables for ultralow topography and CMP for memory devices. Part two addresses consumables and process control for improved CMP and includes chapters on CMP pads, diamond disc pad conditioning, the use of FTIR spectroscopy for characterization of surface processes and approaches for defection characterization, mitigation, and reduction. Advances in Chemical Mechanical Planarization (CMP), Second Edition is an invaluable resource and key reference for materials scientists and engineers in academia and R&D. Reviews the most relevant techniques and processes for CMP of dielectric and metal films Includes chapters devoted to CMP for current and emerging materials Addresses consumables and process control for improved CMP, including post-CMP
| Author | : Joseph M. Steigerwald |
| Publisher | : John Wiley & Sons |
| Total Pages | : 337 |
| Release | : 2008-09-26 |
| Genre | : Science |
| ISBN | : 3527617752 |
Chemical Mechanical Planarization (CMP) plays an important role in today's microelectronics industry. With its ability to achieve global planarization, its universality (material insensitivity), its applicability to multimaterial surfaces, and its relative cost-effectiveness, CMP is the ideal planarizing medium for the interlayered dielectrics and metal films used in silicon integrated circuit fabrication. But although the past decade has seen unprecedented research and development into CMP, there has been no single-source reference to this rapidly emerging technology-until now. Chemical Mechanical Planarization of Microelectronic Materials provides engineers and scientists working in the microelectronics industry with unified coverage of both the fundamental mechanisms and engineering applications of CMP. Authors Steigerwald, Murarka, and Gutmann-all leading CMP pioneers-provide a historical overview of CMP, explain the various chemical and mechanical concepts involved, describe CMP materials and processes, review the latest scientific data on CMP worldwide, and offer examples of its uses in the microelectronics industry. They provide detailed coverage of the CMP of various materials used in the making of microcircuitry: tungsten, aluminum, copper, polysilicon, and various dielectric materials, including polymers. The concluding chapter describes post-CMP cleaning techniques, and most chapters feature problem sets to assist readers in developing a more practical understanding of CMP. The only comprehensive reference to one of the fastest growing integrated circuit manufacturing technologies, Chemical Mechanical Planarization of Microelectronic Materials is an important resource for research scientists and engineers working in the microelectronics industry. An indispensable resource for scientists and engineers working in the microelectronics industry Chemical Mechanical Planarization of Microelectronic Materials is the only comprehensive single-source reference to one of the fastest growing integrated circuit manufacturing technologies. It provides engineers and scientists who work in the microelectronics industry with unified coverage of both the fundamental mechanisms and engineering applications of CMP, including: * The history of CMP * Chemical and mechanical underpinnings of CMP * CMP materials and processes * Applications of CMP in the microelectronics industry * The CMP of tungsten, aluminum, copper, polysilicon, and various dielectrics, including polymers used in integrated circuit fabrication * Post-CMP cleaning techniques * Chapter-end problem sets are also included to assist readers in developing a practical understanding of CMP.
| Author | : Viral Pradeep Lowalekar |
| Publisher | : |
| Total Pages | : 474 |
| Release | : 2006 |
| Genre | : |
| ISBN | : |
In an ECMP process, a wafer is anodically baised during polishing. The electrical potential is the driving force to oxidize copper metal to ions. Copper ions then react with chemistry in the electrolyte to go in solution or form a passivation layer on the surface. The passivation layer is removed by a very low downforce (0.5-1 psi), causing copper to electrochemically dissolve in solution. Passive film formation during copper ECMP is key to the success of this process, since passivation reduces dissolution in the recessed areas, while elevations on the copper surface in direct contact with the ECMP pad are electrochemically planarized. If no passive film forms, then copper removal will be conformal from the elevated and recessed areas, and planarity will be lost. Chemical formulations for the electrochemical mechanical planarization (ECMP) of copper must contain constituents that are stable at anodic potentials. A key component of the formulation is a corrosion inhibitor, which is required to protect low lying areas while higher areas are selectively removed. Organic compounds, which adsorb on copper at low overpotentials and form a film by oxidation at higher overpotentials, may be particularly useful for ECMP. The main goal of the research reported in this dissertation is to understand and develop oxalic acid-based chemical systems suitable for ECMP of copper through electrochemical and surface investigations. Special attention was paid to the development of an inhibitor, which can function under applied potential conditions. Physical methods such as profilometry and four point probe were used to obtain copper removal rates. An organic compound, thiosalicylic acid (TSA), was identified and tested as a potential corrosion inhibitor for copper. TSA offers better protection than the conventionally used benzotriazole (BTA) by oxidizing at high anodic potentials to form a passive film on the copper surface. The passive film formed on the copper surface by addition of TSA was characterized by X-ray photoelectron spectroscopy. The oxidation potential of TSA was characterized using cyclic voltammetry. The passivation and repassivation kinetics was investigated in detail and a passivation mechanism of copper in oxalic acid in the presence of TSA is proposed. Copper removal experiments were performed on a specially designed electrochemical abrasion cell (EC-AC) in both the presence and absence of inhibitors. The effect of anodic potentials on the dissolution of copper was studied to identify suitable conditions for the electro-chemical mechanical planarization process.
| Author | : Shantanu Tripathi |
| Publisher | : |
| Total Pages | : 404 |
| Release | : 2008 |
| Genre | : |
| ISBN | : |
| Author | : Sudipta Seal |
| Publisher | : The Electrochemical Society |
| Total Pages | : 370 |
| Release | : 2003 |
| Genre | : Technology & Engineering |
| ISBN | : 9781566774048 |
| Author | : Veera Raghava R. Kakireddy |
| Publisher | : |
| Total Pages | : |
| Release | : 2007 |
| Genre | : |
| ISBN | : |
ABSTRACT: The effects of different process parameters on tribology and surface defects were studied till date, but there has been a very minimal study to understand the effect of slurry temperature during Copper Chemical Mechanical Polishing (CMP). The surface defects such as dishing, erosion and metal loss amount for more than 50% of the defects that hamper the device yield and mainly the electrical properties during the manufacturing process. In this research, the effect of slurry temperature on tribology, surface defects and electrical properties during copper CMP employing different pad materials and slurries has been explored. Experiments were conducted at different slurry temperatures maintaining all the other process parameters constant. Post polished copper samples were analyzed for their dishing and metal loss characteristics. From the results, it was seen that the coefficient of friction and removal rate increased with increase in slurry temperature during polishing with both types of polishing pads. This increase in removal rate is attributed to a combined effect of change in pad mechanical properties and chemical reaction kinetics. The experimental data indicated that the increase in slurry temperature results in an increase in amounts of metal dishing and copper metal loss for one type of slurry and defects decrease with increase in slurry temperature for other type of slurry. This phenomenon indicates the effect of temperature on chemical reaction kinetics and its influence on defect generation. This can be attributed due to the change in pad asperities due to change in pad mechanical properties and chemical kinetics with change in slurry temperature. The slurry temperature has an effect not only on the surface defects and tribology but also on the change in pad mechanical properties. The copper thin films peeled off at higher polishing temperatures, leading to adhesion failure. With increase in temperature the copper crystallinity, hardness and modulus increased. Further with increase in the defects the electrical properties of the devices also degraded drastically and even failed to operate at higher levels of dishing and metal loss. This research is aimed at understanding the physics governing the defect generation during CMP.
| Author | : Iqbal Ali |
| Publisher | : The Electrochemical Society |
| Total Pages | : 294 |
| Release | : 1997 |
| Genre | : Science |
| ISBN | : 9781566771726 |
| Author | : Ashutosh Misra |
| Publisher | : John Wiley & Sons |
| Total Pages | : 386 |
| Release | : 2002-03-22 |
| Genre | : Science |
| ISBN | : 0471316717 |
The first comprehensive guide to the chemicals and gases used in semiconductor manufacturing The fabrication of semiconductor devices involves a series of complex chemical processes such as photolithography, etching, cleaning, thin film deposition, and polishing. Until now, there has been no convenient source of information on the properties, applications, and health and safety considerations of the chemicals used in these processes. The Handbook of Chemicals and Gases for the Semiconductor Industry meets this need. Each of the Handbook's eight chapters is related to a specific area of semiconductor processing. The authors provide a brief overview of each step in the process, followed by tables containing physical properties, handling, safety, and other pertinent information on chemicals and gases typically used in these processes. The 270 chemical and gas entries include data on physical properties, emergency treatment procedures, waste disposal, and incompatible materials, as well as descriptions of applications, chemical mechanisms involved, and references to the literature. Appendices cross-reference entries by process, chemical name, and CAS number. The Handbook's eight chapters are: Thin Film Deposition Materials Wafer Cleaning Materials Photolithography Materials Wet and Dry Etching Materials Chemical Mechanical Planarizing Methods Carrier Gases Uncategorized Materials Semiconductor Chemicals Analysis No other single source brings together these useful and important data on chemicals and gases used in the manufacture of semiconductor devices. The Handbook of Chemicals and Gases for the Semiconductor Industry will be a valuable reference for process engineers, scientists, suppliers to the semiconductor industry, microelectronics researchers, and students.
