Collapse Mechanisms for High Aspect Ratio Structures with Application to Clean Processing

Peter, Daniel; Holsteyns, Frank; Dalmer, Michael; Kruwinus, Hans; Lechner, Alfred; Bensch, Wolfgang

doi:10.1149/1.3202659

Cited by 8 publications

(8 citation statements)

References 12 publications

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“…This factor can be applied to the absolute values but does not change the relative results. The absolute forces determined by the original method yield a good agreement with a finite element model presented in earlier work [19] and the literature [4]. In DI water, for example, this resulted in collapse forces of 4.2 μN with the original method [16] and 12.6 μN with the modified one [17].…”

Section: Fracture Forcessupporting

confidence: 75%

“…the rupture occurs inside the polysilicon. Also the stress levels calculated by finite element analysis (2-3 GPa) corresponded to the reported fracture strength of polysilicon [19].…”

Section: Rupture Modelmentioning

confidence: 56%

“…Usually, a crack initiates at a material defect or an interface in a high stress region. In this case, it could be shown that the rupture line was located inside the polysilicon and did not touch the polysilicon-SiON interface [19], i.e. the rupture occurs inside the polysilicon.…”

Section: Rupture Modelmentioning

confidence: 92%

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Measurement of the mechanical stability of semiconductor line structures in drying liquids with application to pattern collapse

Peter

Dalmer

Lechner

et al. 2011

J. Micromech. Microeng.

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Enhanced particle removal processes in wet cleaning as well as drying processes of semiconductor wafers can cause significant lateral forces on surface structures. These forces, however, must not exceed the mechanical stability of structures on the wafer. Thus, a mechanical fracture test was used to assess the lateral mechanical stability of polysilicon line structures in relevant process liquids. The mechanical test was based on nanomanipulation with an atomic force microscope. Compared to fracture tests in air, data acquired in liquid isopropanol revealed a stabilizing effect. The differences in fracture forces can be attributed to a stress corrosion process on the surface. The size of the generated damage was influenced by the viscosity of the surrounding media.

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Section: Fracture Forcessupporting

confidence: 75%

“…the rupture occurs inside the polysilicon. Also the stress levels calculated by finite element analysis (2-3 GPa) corresponded to the reported fracture strength of polysilicon [19].…”

Section: Rupture Modelmentioning

confidence: 56%

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Measurement of the mechanical stability of semiconductor line structures in drying liquids with application to pattern collapse

Peter

Dalmer

Lechner

et al. 2011

J. Micromech. Microeng.

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“…1,2 These physical and chemical approaches cannot only lead to the increase in material loss and surface damage but also are troublesome at present, such as chemicals and disposals cost, ultrapure water consumptions, environmental burdens, etc. 3 Furthermore, as the feature size for integrated circuits continues to shrink down, the removal of HDI PR and postetch residues in the trenches/vias with high aspect ratio structure is extremely difficult in aqueous-based cleaning solutions due to their high surface tension and capillarity. The residues at the bottom of the trenches/vias will increase the contact resistance of interconnects, which will affect the subsequent process and eventually degrade the device performance.…”

mentioning

confidence: 99%

The Stripping Behavior of High-Dose Ion-Implanted Photoresists in Supercritical CO₂Formulations

Han

Wang

et al. 2013

ECS J. Solid State Sci. Technol.

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A new type of high-dose ion-implanted photoresist (HDI PR) stripping method was reported based on supercritical CO 2 (scCO 2 ) microemulsions consisting of branched hydrocarbon surfactant 2-ethyl hexanol polyoxyethylene-polyoxypropylene (EH-3) and co-solvent dimethylsulfoxide (DMSO). The optimized concentration of EH-3 and DMSO in scCO 2 were 3 wt% and 2 vol.%, respectively, and the ratio of H 2 O and EH-3 is 1:1. The post-etch HDI PRs containing crust polymer were removed in the scCO 2 microemulsions under the pressure of 10-25 MPa at 40-80 • C for 10 min. The results revealed that the stripping efficiency increased with the pressure and temperature when the temperature is lower than 60 • C. The 94% removal efficiency was achieved at 60 • C and 20 MPa and then it gradually decreased as the temperature is higher than 60 • C due to the lower scCO 2 density at higher temperature. The magnetic agitation and pressure pulsation were favorable to HDI PR removal. The optimum stripping parameters were determined to be 60 • C and 25 MPa for 20 min at which 100% photoresist removal efficiency was achieved in EH-3/DMSO/scCO 2 microemulsions. This environmentally benign method provides a promising alternative to effectively strip the HDI PR for nano-sized devices in microelectronics processing.The complete and effective stripping of high-dose ion-implanted photoresist (HDI PR) in IC manufacturing has become more challenging as the level of photoresist has increased while the allowable material loss and surface damage has decreased with the chip size downscaling. The heavily implanted photoresist is extremely difficult to be removed because an amorphous carbonized crust is formed due to the reaction of the implanted cation with the photoresist polymer as ion-implant dose is greater than 5 × 10 14 atoms/cm 2 and this crust is insoluble in wet chemicals. Usually, this kind of HDI PR removal has been achieved through a combination of dry plasma ashing and a subsequent wet chemical treatment with sulfuric acid and hydrogen peroxide mixture at elevated temperature. 1,2 These physical and chemical approaches cannot only lead to the increase in material loss and surface damage but also are troublesome at present, such as chemicals and disposals cost, ultrapure water consumptions, environmental burdens, etc. 3 Furthermore, as the feature size for integrated circuits continues to shrink down, the removal of HDI PR and postetch residues in the trenches/vias with high aspect ratio structure is extremely difficult in aqueous-based cleaning solutions due to their high surface tension and capillarity. The residues at the bottom of the trenches/vias will increase the contact resistance of interconnects, which will affect the subsequent process and eventually degrade the device performance. To fabricate smaller devices, low conductivity (ρ) copper and low dielectric constant (k) insulator are usually required to replace Al and SiO 2 as interconnects and inter-metal dielectrics, respectively, to minimize the resistance-capacitance (RC) coupli...

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“…The crystal mismatch and the roughness at the interface might explain the difference in pattern collapse forces. The corner rounding at the border of interface could influence the distribution of stress which could reduce the rupture at the interface [5]. However, it is difficult to control the corner rounding itself and a stronger collapse force at a smaller corner rounding as shown in Fig.…”

mentioning

confidence: 99%

Effects of Interfacial Strength and Dimension of Structures on Physical Cleaning Window

Kim¹,

Pacco²,

Brems

et al. 2012

SSP

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Four different types of FINs; amorphous Si (a-Si), annealed a-Si, polycrystalline Si (poly-Si) and crystalline Si (c-Si) were used to investigate the effect of interfacial strength and the length of structures on the physical cleaning window by measuring their collapse forces by atomic force microscope (AFM). A transmission electron microscope (TEM) and a nanoneedle with a nanomanipulator in a scanning electron microscope (SEM) were employed in order to explain the different collapse behavior and their forces. Different fracture shapes and collapse forces of FINs could explain the influence of the interfacial strength on the pattern strength. Furthermore, the different lengths of a-Si FINs were prepared and their collapse forces were measured and the shorter length reduced their pattern strength. Strong adhesion at the interface resulted in a wider process window while smaller dimensions made the process window narrower.

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Collapse Mechanisms for High Aspect Ratio Structures with Application to Clean Processing

Cited by 8 publications

References 12 publications

Measurement of the mechanical stability of semiconductor line structures in drying liquids with application to pattern collapse

Measurement of the mechanical stability of semiconductor line structures in drying liquids with application to pattern collapse

The Stripping Behavior of High-Dose Ion-Implanted Photoresists in Supercritical CO₂Formulations

Effects of Interfacial Strength and Dimension of Structures on Physical Cleaning Window

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Collapse Mechanisms for High Aspect Ratio Structures with Application to Clean Processing

Cited by 8 publications

References 12 publications

Measurement of the mechanical stability of semiconductor line structures in drying liquids with application to pattern collapse

Measurement of the mechanical stability of semiconductor line structures in drying liquids with application to pattern collapse

The Stripping Behavior of High-Dose Ion-Implanted Photoresists in Supercritical CO2Formulations

Effects of Interfacial Strength and Dimension of Structures on Physical Cleaning Window

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Product

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The Stripping Behavior of High-Dose Ion-Implanted Photoresists in Supercritical CO₂Formulations