Tribological, Kinetic and Thermal Characteristics of Copper Chemical Mechanical Planarization PDF Download
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Author:
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ISBN:
Category :
Languages : en
Pages : 612
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Book Description
Copper polishing performance depends significantly on the properties of pads, slurries, conditioning, pressure, sliding velocity, slurry flow rate and temperature. A slight variance in each of these parameters will cause significant change in polising results. Various investigations are performed during this study to understand the effect of consumables and other main operating parameters on copper polishing in terms of removal rate, lubrication mechanism, and temperature transients. A modified two-step Langmuir-Hinshelwood removal rate model and a flash heating thermal model are developed to describe the removal mechanism. Results indicate that grain size plays an important role during copper polishing. Smaller grain size may enhance the chemical rate by providing a higher density of favorable reaction sites. However, denser grain boundaries due to smaller grain size may reduce the mechanical rate by increasing the probability of disruption of three body sliding contact. It is found that removal rate increases as slurry flow increases from 60 to 80 cc/min because higher slurry flow rate can provide more reactants to the system. Then removal rate decreases as slurry flow rate is further increased to 140 cc/min, which is due to synergic effects of the wafer temperature, slurry flow and slurry residence time under the wafer. The observed removal rate drop is thought to be due to the change of the wafer temperature at high sliding velocity. Experimental results from eight slurry formulations with various abrasize size and content show that in the case of 13-nm abrasives, the dominant tribological mechanism is that of partial lubrication, while in the case of 35-nm abrasives, the dominant tribological mechanism is that of boundary lubrication. COF values of the slurry with surfactant are generally lower that those of the slurry without surfactant. Logarithmic spiral positive pad, whose spiral groove is at a slight angle to the pad rotation direction, shows the highest average COF. The radial pad results in the smallest average COF. For all types of the grooved pads investigated, CMP is mechanically limited at low pV, and chemically limited at high pV. Non-Prestonian behavior is thought to be due to variations of COF and substrate temperatures. Dual Emission UV Light Enhanced Fluorescence results indicate that during polishing the wafer is tilted towards the center of the pad and that the extent of wafer tilt is a strong function of diamond disc pressure. Increasing the oscillation frequency of the diamond disc or the rotation rate decreases slurry film thickness. Slurry film thickness increases with the slurry flow rate. Also slurry film thickness strongly depends on diamond disc design.
Author:
Publisher:
ISBN:
Category :
Languages : en
Pages : 612
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Book Description
Copper polishing performance depends significantly on the properties of pads, slurries, conditioning, pressure, sliding velocity, slurry flow rate and temperature. A slight variance in each of these parameters will cause significant change in polising results. Various investigations are performed during this study to understand the effect of consumables and other main operating parameters on copper polishing in terms of removal rate, lubrication mechanism, and temperature transients. A modified two-step Langmuir-Hinshelwood removal rate model and a flash heating thermal model are developed to describe the removal mechanism. Results indicate that grain size plays an important role during copper polishing. Smaller grain size may enhance the chemical rate by providing a higher density of favorable reaction sites. However, denser grain boundaries due to smaller grain size may reduce the mechanical rate by increasing the probability of disruption of three body sliding contact. It is found that removal rate increases as slurry flow increases from 60 to 80 cc/min because higher slurry flow rate can provide more reactants to the system. Then removal rate decreases as slurry flow rate is further increased to 140 cc/min, which is due to synergic effects of the wafer temperature, slurry flow and slurry residence time under the wafer. The observed removal rate drop is thought to be due to the change of the wafer temperature at high sliding velocity. Experimental results from eight slurry formulations with various abrasize size and content show that in the case of 13-nm abrasives, the dominant tribological mechanism is that of partial lubrication, while in the case of 35-nm abrasives, the dominant tribological mechanism is that of boundary lubrication. COF values of the slurry with surfactant are generally lower that those of the slurry without surfactant. Logarithmic spiral positive pad, whose spiral groove is at a slight angle to the pad rotation direction, shows the highest average COF. The radial pad results in the smallest average COF. For all types of the grooved pads investigated, CMP is mechanically limited at low pV, and chemically limited at high pV. Non-Prestonian behavior is thought to be due to variations of COF and substrate temperatures. Dual Emission UV Light Enhanced Fluorescence results indicate that during polishing the wafer is tilted towards the center of the pad and that the extent of wafer tilt is a strong function of diamond disc pressure. Increasing the oscillation frequency of the diamond disc or the rotation rate decreases slurry film thickness. Slurry film thickness increases with the slurry flow rate. Also slurry film thickness strongly depends on diamond disc design.
Author: Veera Raghava R. Kakireddy
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
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: Sudipta Seal
Publisher: The Electrochemical Society
ISBN: 9781566774048
Category : Technology & Engineering
Languages : en
Pages : 370
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Book Description
Author: Y. Zhuang
Publisher:
ISBN:
Category : Chemical engineering
Languages : en
Pages :
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Book Description
Author: Swetha C. Thagella
Publisher:
ISBN:
Category : Grinding and polishing
Languages : en
Pages : 186
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Book Description
Author: Hong Liang
Publisher: CRC Press
ISBN: 1420028391
Category : Technology & Engineering
Languages : en
Pages : 199
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Book Description
Illustrating their intersecting role in manufacturing and technological development, this book examines tribological principles and their applications in CMP, including integrated circuits, basic concepts in surfaces of contacts, and common defects as well as friction, lubrication fundamentals, and the basics of wear. The book concludes its focus with mechanical aspects of CMP, pad materials, elastic modulus, and cell buckling. As the first source to integrate CMP and tribology, Tribology in Chemical-Mechanical Planarization provides applied scientists and engineers in the fields of semiconductors and microelectronics with clear foresight to the future of this technology.
Author: Daniel Rosales-Yeomans
Publisher:
ISBN:
Category :
Languages : en
Pages : 854
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Book Description
The present dissertation includes several studies that describe the effects of novel groovedesigns on the tribological, thermal and kinetic characteristics of ILD and copper CMP. A novelIPL-FMC 200-mm polisher, in which friction force could be obtained in two directions, was introduced and compared to lab-scale (IPL 100-mm) polisher during ILD CMP. Results showed that scaling the ILD process from 100 to 200 mm caused a transition from a mechanically-limited regime, in which it was still possible to detect thermal effects, to a higher degree of mechanical limitation where it was no longer possible to detect thermal effects. Other studies in this dissertation were related to the evaluation and modeling of novel groove designs for copper CMP optimization. Novel groove designs were divided into two groups: (1) Logarithmic-Spiral and (2) Concentric Slanted. These novel groove designs were evaluated under several operating conditions, such as wafer load, sliding velocity and slurry flow rate. This work resulted in the identification of one novel groove design from each group, which resulted in high Copper RR. The observed RR behavior was attributed to two possible scenarios. Firstly, it was believed that these novel groove designs produced a more effective control of the transport of slurry into, and the discharge of spent slurry and debris out of, the pad-wafer interface. Secondly, the variations in slurry film thickness at the pad-wafer interface generated by the different groove designs evaluated, appeared to affect the degree of contact between the pad and the wafer; hence the mechanical (pad asperities-wafer contact) and chemical(rise in temperature) contributions of the system. A novel 3-Step copper removal model wasapplied to copper CMP. The model predicted remarkably well the removal rate behavior during copper polishing for different pad groove designs. The model allowed us to perform an analysis of the effect of groove designs on the chemical and mechanical contribution of the system.
Author:
Publisher:
ISBN:
Category : Dissertations, Academic
Languages : en
Pages : 946
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Book Description
Author: Frank A. Giglio
Publisher:
ISBN:
Category : Grinding and polishing
Languages : en
Pages : 126
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Book Description
Author: Duane S. Boning
Publisher:
ISBN:
Category : Technology & Engineering
Languages : en
Pages : 376
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Book Description
Chemical-mechanical planarization (CMP) has emerged as a critical fabrication technology for advanced integrated circuits. Even as the applications of CMP have diversified and we have begun to understand aspects of the physics and chemistry of the process, a new generation of CMP innovations is unfolding. New slurries and consumables are under development. New applications to novel devices continue to appear. This book, the most recent in a successful series on CMP, offers a review of the advances to date and provides a comprehensive discussion of the future challenges that must be overcome. Presentations from academia, government labs and industry are featured. Topics include; CMP modeling; CMP science; CMP slurries and particles for planarization of copper, oxide, and other materials; planarization applications including shallow trench isolation (STI), copper damascene, and novel devices and CMP integration.
