The Effect of Material and Process Interactions on BEOL Integration

Spooner, T.; Arnold, John; Canaperi, D.; Chen, James; Chen, Shyng-Tsong; Gates, S. M.; Isobayashi, A.; Leung, Pak Sing; Rao, Satyavolu S. Papa; Sankarapandian, M.; Shobha, H.; Straten, O. van der

doi:10.1149/1.3203966

Cited by 10 publications

(10 citation statements)

References 7 publications

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“…Specifically, Goto et al, 393 and Liu et al, 394 have both observed UV cure induced hydrogen loss and more dramatic compressiveto-tensile (-250 MPa to 100 MPa) stress changes in PECVD SiCNH Cu cap materials. Even more dramatic -500 MPa to 750 MPa stress swings have been reported by Spooner et al 9 Liu also observed using FTIR that significant UV-induced structural modifications occurred for SiCNH Cu cap materials with higher nitrogen and hydrogen content. 394 Interestingly though, small (< 1-2%) changes in dielectric constant and film thickness for SiCNH and SiOCH Cu cap materials with UV curing were observed relative to pSiOCH materials.…”

Section: Vi2 Film Stress Engineeringmentioning

confidence: 68%

“…7 One significant impact of this incidental exposure is UV-induced stress changes in the Cu cap layer, typically SiNH or SiCN, on which the pSiCOH film is deposited. 8,9 Since interconnects are composed of up to a dozen wiring layers, 6 the stress of each layer is additive and can subject the interconnect wiring levels to substantial stresses. In some cases, the tensile stress can become high enough to induce cracking in the pSiCOH film, especially when the wafer is subjected to additional stresses during the chip packaging process.…”

Section: Vi2 Film Stress Engineeringmentioning

confidence: 99%

“…One method demonstrated by Spooner involves simply tuning the PECVD process to produce films with increasingly higher levels of compressive stress such that the films remain compressive after the UV cure. 9 As shown by Nguyen et al, this can be achieved by increasing the H2 dilution flow during PECVD using trimethylsilane (Si(CH3)3H) and ammonia (NH3). 7 Other methods for mitigating the ILD UV-cure impact on the Cu capping layer stress involve employing a SiCNH/SiNH bilayer or SiCNH/SiNH/SiNH tri-layer film stack to mitigate the  impact of using a higher compressive stress / higher  material to compensate for the increased tensile stress component induced by the UV irradiation.…”

Section: Vi2 Film Stress Engineeringmentioning

confidence: 99%

“…One consequence was a UV-induced change in stress from compressive to tensile in SiCNH films used to passivate the top Cu surface. 7,8,9 Films with modestly compressive or neutral stress are desired because tensile films can induce cracking during the chip packaging process. Thus, there was a need to understand how UV light affects all the films used to fabricate BEOL interconnects.…”

Section: Introductionmentioning

confidence: 99%

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Impact of VUV photons on SiO2 and organosilicate low-k dielectrics: General behavior, practical applications, and atomic models

Baklanov

Jousseaume

Рахимова

et al. 2019

Applied Physics Reviews

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This paper presents an in-depth overview of the application and impact of UV/VUV light in advanced interconnect technology. UV light application in BEOL historically was mainly motivated by the need to remove organic porogen and generate porosity in organosilicate (OSG) low-k films. Porosity lowered the film's dielectric constant, k, which enables one to reduce the interconnect wiring capacitance contribution to the RC signal delay in integrated circuits. The UV-based low-k film curing (λ > 200 nm) proved superior to thermal annealing and electron beam curing. UV and VUV light also play a significant role in plasma-induced damage to pSiCOH. VUV light with λ < 190–200 nm is able to break Si-CH3 bonds and to make low-k materials hydrophilic. The following moisture adsorption degrades the low-k properties and reliability. This fact motivated research into the mechanisms of UV/VUV photon interactions in pSiCOH films and in other materials used in BEOL nanofabrication. Today, the mechanisms of UV/VUV photon interactions with pSiCOH and other films used in interconnect fabrication are fairly well understood after nearly two decades of research. This understanding has allowed engineers to both control the damaging effects of photons and utilize the UV light for material engineering and nanofabrication processes. Some UV-based technological solutions, such as low-k curing and UV-induced stress engineering, have already been widely adopted for high volume manufacturing. Nevertheless, the challenges in nanoscaling technology may promote more widespread adoption of photon-assisted processing. We hope that fundamental insights and prospected applications described in this article will help the reader to find the optimal way in this wide and rapidly developing technology area.

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Section: Vi2 Film Stress Engineeringmentioning

confidence: 68%

Section: Vi2 Film Stress Engineeringmentioning

confidence: 99%

Section: Vi2 Film Stress Engineeringmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Impact of VUV photons on SiO2 and organosilicate low-k dielectrics: General behavior, practical applications, and atomic models

Baklanov

Jousseaume

Рахимова

et al. 2019

Applied Physics Reviews

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“…In particular, it has been determined that the dielectric constant of SiO 2 can be reduced by using doping with carbon-containing organics. ,, The resulting SiCOH materials have dielectric constants in the range from 2.7 to 3.0, and even lower values are possible by adding porosity. On the flip side, these new materials exhibit limited chemical stability, requiring special care during microelectronics manufacturing. ,− One of most difficult challenges when patterning the SiCOH dielectric is to minimize damage during the photoresist stripping processes, which typically relies on the use of plasmas with ions and radicals that can remove methyl groups from the surface of the SiCOH. , Because of this, the surface becomes hydrophilic, facilitating water absorption and leading to an increase in the dielectric constant of the material. ,, Several processes have been developed to minimize these problems, but those are multistep and introduce additional complications. ,− …”

Section: Introductionmentioning

confidence: 99%

Chemical Treatment of Low-k Dielectric Surfaces for Patterning of Thin Solid Films in Microelectronic Applications

Guo

Qin

Zaera

2016

ACS Appl. Mater. Interfaces

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A protocol has been developed to selectively process low-k SiCOH dielectric substrates in order to activate or deactivate them toward the deposition of thin solid films by chemical (CVD or ALD) means. The original SiCOH surfaces are hydrophobic, an indication that they are alkyl- rather than silanol-terminated and that, consequently, they are fairly unreactive. However, the chemical-mechanical polishing (CMP) sometimes done during microelectronics fabrication renders them hydrophilic and reactive. It was shown here that silylation of the CMP-treated surfaces with any of a number of well-known silylation agents such as HMDS, ODTS, or OTS caps the reactive silanol surface groups and turns them back to being hydrophilic and unreactive. Further exposure of any of the passivated surfaces to a combination of ozone and UV radiation reinstates their hydrophilicity and chemical activity. Importantly, it was also demonstrated that all these changes could be induced without altering the original mechanical, optical, or electrical properties of the samples: atomic force microscopy (AFM) images show no increase in roughness, ellipsometry measurements yield the same values for the index of refraction and dielectric constant, and infrared absorption spectroscopy attests to the preservation of the organic fragments present in the original SiCOH samples. The chemical selectivity of the resulting surfaces was tested for the atomic layer deposition (ALD) of HfO2 films, which could be grown only on the UV/O3 treated substrates.

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