A 3D EHL Simulation of CMP

Jin, Xiaoqing; Keer, Leon M.; Wang, Qian

doi:10.1149/1.1823993

Cited by 25 publications

(17 citation statements)

References 24 publications

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“…So, strictly speaking, the wafer-surface tilting has to be taken into account in the model to ensure that the resultant moment with respect to the ball joint due to the contact stress, fluid pressure, and friction acting on the wafer surface is zero. However, since the tilting angle of the wafer surface usually is extremely small (on the order of a few micro radians in the calculations of Jin et al [12]), for simplicity we will not explicitly consider the moment balance here.…”

Section: Contact-stress Calculationmentioning

confidence: 99%

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Modeling and calculation of slurry-chemistry effects on chemical–mechanical planarization with a grooved pad

Wang

Yang

2008

J Eng Math

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During chemical-mechanical planarization (CMP), a rotating wafer is pressed against a rotating pad, while a slurry is dragged into the pad-wafer interface. Here, taking into account the dependence of local material removal rate (MRR) on the slurry's chemical activity, the effects of pad groove geometry and various other process parameters on the spatial average and non-uniformity of MRR are examined. Technically, the slurry flow is calculated by following an existing approach that integrates two-dimensional fluid-film lubrication theory and contact-mechanics models. A slurry impurity transport equation is then used to calculate the impurity concentration that determines the slurry's chemical activity and hence the local MRR. The numerical results obtained here indicate that the presence of pad grooves generally decreases the average slurry impurity concentration, and increases the average contact stress on the pad-wafer interface. However, as a grooved pad has less contact area for effective interaction with the wafer surface, the average MRR may or may not be increased, depending upon the specific setting of process parameters. Meanwhile, it appears that the retaining ring generally used to keep the wafer in place also plays an important part in reducing the MRR non-uniformity.

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Section: Contact-stress Calculationmentioning

confidence: 99%

“…A number of other theoretical models exist in the literature (e.g., [10][11][12]), each considering certain aspects of the CMP process. To our knowledge, one of the simplest models that calculates the contact stress on the pad-wafer interface, which then determines the slurry-film thickness, was proposed by Shan et al [11] for CMP with a flat pad.…”

mentioning

confidence: 99%

Modeling and calculation of slurry-chemistry effects on chemical–mechanical planarization with a grooved pad

Wang

Yang

2008

J Eng Math

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“…Most existing models e.g. [12,[19][20][21][22] have treated the polishing pad according to the Greenwood-Williamson theory [23] as a rough engineering surface with protruding asperities whose heights follow the Gaussian distribution. The asperities are assumed to be capped with spherical peaks of uniform radius.…”

Section: Contact Mechanicsmentioning

confidence: 99%

“…Equation (20) shows that the probability P 0 that no defects in the wafer fail is a function only of the critical number of contacts n c , the mean number of asperity contacts k and the total number of defects N w . Alternatively, the mean number of asperity contacts k required for a given probability of delamination (here taken for the polishing tests as 50%), can be found given n c and N w .…”

Section: Fatigue Modelmentioning

confidence: 99%

“…Then the micro-tribometer test, with a Hertz pressure p m the same as " p gives the critical number of contacts to failure n c , while equation (15) provides the defect density q d . Equation (20) is used to calculate the mean number of asperity contacts k to give a 50% chance of delamination failure, and equation (21) gives the corresponding time t. The defect length ' is the only parameter that has to be obtained by estimation in this statistical model. Figure 14 summarises the above algorithm, showing the calculation procedure for predicting the polishing time to delamination in the polishing experiments based on the micro-tribometer experimental results.…”

Section: Fatigue Modelmentioning

confidence: 99%

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Modelling of delamination of ultra low-k material during chemical mechanical polishing

Liu

Sutcliffe

2006

Tribol Lett

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Two sets of experiments are performed to examine the delamination mechanism of ultra low-k material during chemical mechanical polishing (CMP): (i) a macro-scale polishing test using a metallographic polisher and (ii) a micro-scale scratch test on a micro-tribometer. Delamination has been observed at higher pressures in both sets of experiments and the relationship between delamination rate and pressure has been established. Contact mechanics models are proposed to correlate results from the two sets of experiments, combining a Weibull model of failure with a statistical asperity contact model. Results confirm the usefulness of the combined testing procedure in predicting safe polishing pressures during CMP.

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Synergetic effects of wafer rigidity and retaining-ring parameters on contact stress uniformity in chemical mechanical planarization

Yang

Chen

2011

Int J Adv Manuf Technol

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A 3D EHL Simulation of CMP

Cited by 25 publications

References 24 publications

Modeling and calculation of slurry-chemistry effects on chemical–mechanical planarization with a grooved pad

Modeling and calculation of slurry-chemistry effects on chemical–mechanical planarization with a grooved pad

Modelling of delamination of ultra low-k material during chemical mechanical polishing

Synergetic effects of wafer rigidity and retaining-ring parameters on contact stress uniformity in chemical mechanical planarization

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