Effect of polishing pad with holes in electro-chemical mechanical planarization

The calculating model of surface non-uniformity of polishing pad and the kinematical model between polishing pad and conditioner are initially established. Then the effects of several conditioning parameters were investigated by using the two models. The results of simulation and calculation show that the width ratio of diamond band of conditoner and the rotation speed at the same speed ratio between pad and conditioner have little effect on the surface non-uniformity of polishing pad, while at high non-integer rotation speed ratio, the surface non-uniformity of polishing pad is better than that at low integer speed ratio. The research results are available to select appropriate conditioning parameters especially for the stringent requirement of within-wafer non-uniformity in next generation IC.

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Novel Measurement Technique on 3D Surface Topography of Polishing Pad

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.53-54.265 ◽

2008 ◽

Vol 53-54 ◽

pp. 265-272

Author(s):

Dong Ming Guo ◽

N. Qin ◽

Ren Ke Kang ◽

Zhu Ji Jin

Keyword(s):

Surface Topography ◽

Chemical Mechanical Planarization ◽

Sampling Interval ◽

3D Measurement ◽

Sampling Area ◽

Polishing Pad ◽

3D Surface ◽

3D Surface Topography ◽

Planarization Process ◽

Polishing Pads

Among the properties of polishing pad, the surface roughness plays a crucial role in CMP (Chemical Mechanical Planarization) process. However, there is no acknowledged standard for measuring and characterizing the roughness of pad surface in 3D measurement. In this paper Talysurf CLI 2000 working on the principle of dynamic confocal measurement was initially suggested to measure the 3D surface topography of polishing pads through theoretical and experimental analysis. In addition, based on the Nyquist folding frequency and the statistical theory, a selection technique for sampling interval and sampling area was proposed and verified through experiments. The results showed that Talysurf CLI 2000 is more suitable than NewView to measure the 3D surface topography of polishing pads. 2μm sampling interval, 0.5×0.5mm2 sampling area and 10μm interval, 1×1mm2 area are respectively recommended for IC1000/SubaIV and SubaIV polishing pad.

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Effect of conditioner load on the polishing pad surface during chemical mechanical planarization process

Journal of Mechanical Science and Technology ◽

10.1007/s12206-016-1135-0 ◽

2016 ◽

Vol 30 (12) ◽

pp. 5659-5665 ◽

Cited By ~ 7

Author(s):

Cheolmin Shin ◽

Hongyi Qin ◽

Seokjun Hong ◽

Sanghyuk Jeon ◽

Atul Kulkarni ◽

...

Keyword(s):

Chemical Mechanical Planarization ◽

Polishing Pad ◽

Planarization Process

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The Effect of Wafer Shape on Slurry Film Thickness and Friction Coefficients in Chemical Mechanical Planarization

MRS Proceedings ◽

10.1557/proc-613-e1.2.1 ◽

2000 ◽

Vol 613 ◽

Cited By ~ 7

Author(s):

Joseph Lu ◽

Jonathan Coppeta ◽

Chris Rogers ◽

Vincent P. Manno ◽

Livia Racz ◽

...

Keyword(s):

Film Thickness ◽

Drag Force ◽

Chemical Mechanical Planarization ◽

Fluid Film ◽

Ex Situ ◽

Local Pressure ◽

Dual Emission ◽

Polishing Pad ◽

Fluid Film Thickness

ABSTRACTThe fluid film thickness and drag during chemical-mechanical polishing are largely dependent on the shape of the wafer polished. In this study we use dual emission laser induced fluorescence to measure the film thickness and a strain gage, mounted on the polishing table, to measure the friction force between the wafer and the pad. All measurements are taken during real polishing processes. The trends indicate that with a convex wafer in contact with the polishing pad, the slurry layer increases with increasing platen speed and decreases with increasing downforce. The drag force decreases with increasing platen speed and increases with increasing downforce. These similarities are observed for both in-situ and ex-situ conditioning. However, these trends are significantly different for the case of a concave wafer in contact with the polishing pad. During ex-situ conditioning the trends are similar as with a convex wafer. However, in-situ conditioning decreases the slurry film layer with increasing platen speed, and increases it with increasing downforce in the case of the concave wafer. The drag force increases with increasing platen speed as well as increasing downforce. Since we are continually polishing, the wafer shape does change over the course of each experiment causing a larger error in repeatability than the measurement error itself. Different wafers are used throughout the experiment and the results are consistent with the variance of the wafer shape. Local pressure measurements on the rotating wafer help explain the variances in fluid film thickness and friction during polishing.

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A new chemical mechanical planarization with the frozen chemical etchant as a polishing pad

2001 International Semiconductor Device Research Symposium. Symposium Proceedings (Cat. No.01EX497) ◽

10.1109/isdrs.2001.984431 ◽

2002 ◽

Author(s):

Yil-Wook Kim ◽

Jae-Ok Yoo ◽

Tae Woo Jung ◽

Youn-Jin Oh ◽

Chan-Hwa Chung

Keyword(s):

Chemical Mechanical Planarization ◽

Polishing Pad ◽

Chemical Etchant

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Novel electro-chemical mechanical planarization using carbon polishing pad to achieve robust ultra low-k/Cu integration

Proceedings of the IEEE 2005 International Interconnect Technology Conference, 2005. ◽

10.1109/iitc.2005.1499982 ◽

2005 ◽

Author(s):

S. Kondo ◽

S. Tominaga ◽

A. Namiki ◽

K. Yamada ◽

D. Abe ◽

...

Keyword(s):

Chemical Mechanical Planarization ◽

Polishing Pad ◽

Low K

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Study of Conditioner Abrasives in Chemical Mechanical Planarization

MRS Proceedings ◽

10.1557/proc-1157-e08-08 ◽

2009 ◽

Vol 1157 ◽

Author(s):

Chhavi Manocha ◽

Ashok Kumar ◽

Vinay K. Gupta

Keyword(s):

Manufacturing Industry ◽

Surface Defects ◽

Chemical Mechanical Planarization ◽

Factors Affecting ◽

Polishing Pad ◽

Copper Wafers ◽

Pad Wear ◽

Polishing Pads

AbstractChemical Mechanical Planarization (CMP) has emerged as the central technology for polishing wafers in the semiconductor manufacturing industry to make integrated multi-level devices. Both chemical and mechanical processes work simultaneously to achieve local and global planarization. Although extensive research has been carried out to understand the various factors affecting the CMP process, many aspects remain unaddressed. One such aspect of CMP is the role of abrasives in the process of conditioning. Abrasives play an important role during conditioning to regenerate the clogged polishing pads. This research is focused on the study of abrasives in the process of conditioning with a focus on the size of abrasives. With diamond being widely used as an abrasive for conditioning the polishing pad, five different sizes of diamonds ranging from 0.25μm to 100μm were selected to condition the commercially available IC 1000 polishing pad. Properties like pad roughness and pad wear were measured to understand the effect of the abrasive size on the pad morphology and pad topography. In-situ ‘coefficient of friction’ was also monitored on the CETR bench top tester. The final impact was seen in the form of surface defects on the polished copper wafers using optical microscopy.

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Dynamic Pad Surface Metrology Monitoring by Swing-Arm Chromatic Confocal System

Applied Sciences ◽

10.3390/app11010179 ◽

2020 ◽

Vol 11 (1) ◽

pp. 179

Author(s):

Chao-Chang A. Chen ◽

Jen-Chieh Li ◽

Wei-Cheng Liao ◽

Yong-Jie Ciou ◽

Chun-Chen Chen

Keyword(s):

Surface Topography ◽

Removal Rate ◽

Chemical Mechanical Planarization ◽

Surface Profile ◽

Performance Level ◽

Wafer Surface ◽

Surface Metrology ◽

Effective Lifetime ◽

Polishing Pad ◽

Swing Arm

This study aims to develop a dynamic pad monitoring system (DPMS) for measuring the surface topography of polishing pad. Chemical mechanical planarization/polishing (CMP) is a vital process in semiconductor manufacturing. The process is applied to assure the substrate wafer or thin film on wafer that has reached the required planarization after deposition for lithographic processing of the desired structures of devices. Surface properties of polishing pad have a huge influence on the material removal rate (MRR) and quality of wafer surface by CMP process. A DPMS has been developed to analyze the performance level of polishing pad for CMP. A chromatic confocal sensor is attached on a designed fixture arm to acquire pad topography data. By swing-arm motion with continuous data acquisition, the surface topography information of pad can be gathered dynamically. Measuring data are analyzed with a designed FFT filter to remove mechanical vibration and disturbance. Then the pad surface profile and groove depth can be calculated, which the pad’s index PU (pad uniformity) and PELI (pad effective lifetime index) are developed to evaluate the pad’s performance level. Finally, 50 rounds of CMP experiments have been executed to investigate the correlations of MRR and surface roughness of as-CMP wafer with pad performance. Results of this study can be used to monitor the pad dressing process and CMP parameter evaluation for production of IC devices.

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