Heat and Moisture Resistance of Siloxane-Based Low-Dielectric-Constant Materials

Furusawa, Takeshi; Ryuzaki, Daisuke; Yoneyama, Ryo; Homma, Yoshio; Hinode, K.

doi:10.1149/1.1386916

Cited by 37 publications

(27 citation statements)

References 9 publications

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“…It has been reported that lowering the discharge power density decreases the dielectric constant of SiO͑C,H͒ films. 13,14 An increase in the process pressure produces the same effect as seen from our results. This similarity is understandable, as lower discharge power density or higher pressure ͑leading to reduced mean free path of the species͒ both lower the degree of dissociation of the radicals 15,16 and result in an increased incorporation of Si-͑CH 3 ͒ m group in the films.…”

Section: Resultssupporting

confidence: 89%

Effects of Deposition Pressure on Properties of Carbon-Doped Silicon Oxide Low Dielectric Constant Films

Rusli

Wang

Wong

et al. 2005

J. Electrochem. Soc.

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Carbon-doped silicon oxide ͓SiO͑C,H͔͒ dielectric films have been prepared by the plasma-enhanced chemical vapor deposition technique from trimethylsilane in an oxygen ͑O 2 ͒ environment. The process pressure was varied from 1.5 to 8.0 Torr and its effects on the properties of these films have been investigated. The films were also annealed at different temperatures from 400 to 700°C to determine their thermal stability. The thickness, refractive index, dielectric constants, infrared absorption, and surface morphology of the as-deposited and annealed samples were characterized. The dielectric constants of the as-deposited films were found to decrease initially with increasing process pressure and nearly saturate at pressures beyond 4.0 Torr. Dielectric constant as low as 2.86 has been obtained from the as-deposited film at 8.0 Torr process pressure. Lower refractive indexes were also obtained for films deposited at higher pressure. There are no significant changes to the properties of the films upon annealing at temperatures up to 500°C, which is beyond the current highest processing temperature for back end of the line structure of around 450°C. However, beyond that annealing resulted in a sharp increase in the dielectric constants of the films, attributed to the decomposition of CH x and SiCH x bonds.Ultralarge-scale integrated ͑ULSI͒ circuits require the replacement of the SiO 2 interlayer dielectric with low dielectric constants ͑low-k͒ materials to reduce propagation delays, cross-talk noise, and power dissipation arising from resistance-capacitance ͑RC͒ coupling. 1 Low-k materials prepared by the plasma-enhanced chemical vapor deposition ͑PECVD͒ technique are more evolutionary from the current ULSI technology relative to other approaches. Among the PECVD low-k materials, carbon-doped oxide dielectrics ͓SiO͑C,H͔͒ prepared from organosilicon precursor trimethysilane ͑C 3 H 10 Si, also referred to as 3MS͒ is one of the most favorable candidates due to their low-k ͑Ͻ3.0͒ and their key electrical and integration characteristics being similar to those of SiO 2 . 2 The dielectric constant of the PECVD prepared SiO͑C,H͒ films are dependent on the deposition conditions such as temperature, process pressure, radio frequency ͑rf͒ power, and gas flow rate. In our previous work, we have studied SiO͑C,H͒ films deposited with different O 2 /3MS flow ratios at a constant process pressure of 4.0 Torr. 3 The lowest dielectric constant of 2.9 was obtained for the film deposited at a O 2 /3MS flow ratio of 100/600 sccm. In this study, we aim to investigate the effects of process pressure on the characteristics of SiO͑C,H͒ films so as to further optimize the process conditions and lower the dielectric constant. A series of films deposited using the above optimized flow ratio, with the process pressure varied over a wide range from 1.5 to 8.0 Torr, were characterized. Currently, the highest processing temperature for the back end of the line ͑BEOL͒ structure is around 400-450°C, and it is important that any potential low-k dielec...

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Section: Resultssupporting

confidence: 89%

Effects of Deposition Pressure on Properties of Carbon-Doped Silicon Oxide Low Dielectric Constant Films

Rusli

Wang

Wong

et al. 2005

J. Electrochem. Soc.

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“…For the moisture reliability test, the as cured as well as the HWGAH treated HSQ films were immersed in water at 80 -C for 3 h in a closed beaker (container). These conditions were chosen for accelerated testing and are similar to the pressure cooker test (PCT) in an earlier study [6]. The chemical structure of the cured HSQ films before and after the hot wire and water treatment was investigated by Fourier transform infrared (FTIR) spectroscopy.…”

Section: Methodsmentioning

confidence: 99%

Enhancement of moisture resistance of spin-on low-k HSQ films by hot wire generated atomic hydrogen treatment

2006

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“…These results demonstrate that ͑1͒ oxidizing chemistries and reducing chemistries with nitrogen transform the porous SiOCH film in an hydrophilic film, while ͑2͒ nitrogen-free reducing chemistries maintain the hydrophobic properties of the porous SiOCH material. Previous studies [22][23][24][25][26] have shown that in oxidizing plasmas oxygen reactive species can deeply diffuse into the film through the pores and react with methyl groups producing Si-OH bonds leading to moisture uptake. In the case of reducing plasmas with nitrogen, 24-26 hydrogen reactive species ͑NH x ,H͒ can react with Si-O-Si and Si-CH 3 to form Si-NH 2 and Si-OH terminating bonds which can also lead to moisture uptake.…”

Section: Discussionmentioning

confidence: 99%

Modifications of dielectric films induced by plasma ashing processes: Hybrid versus porous SiOCH materials

Darnon

Chevolleau

David

et al. 2008

Journal of Vacuum Science &Amp; Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena

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This work focuses on the impact of oxidizing (O2) and reducing plasma ashing chemistries (NH3, CH4) on the modifications of dielectric materials in a porous or an hybrid state (SiOCH matrix+porogen). The plasma ashing processes have been performed on blanket wafers using O2, NH3, and CH4 based plasmas. The modifications of the remaining film after plasma exposures have been investigated using different analysis techniques such as x-ray photoelectron spectroscopy, infrared spectroscopy, x-ray reflectometry, and porosimetric ellipsometry. For the porous material the authors have shown that NH3 and O2 plasmas induce carbon depletion and moisture uptake while the CH4 plasma only leads to important carbon depletion without moisture uptake and to the formation of a thin carbon layer on the surface. For the hybrid material, no significant material modification is evidenced with the O2 plasma while an important methyl depletion and porogen degradation are observed with reducing chemistries such as CH4 and NH3 plasmas. The impact of the porogen on the film modification and the value of the dielectric constant will be presented and discussed.

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Heat and Moisture Resistance of Siloxane-Based Low-Dielectric-Constant Materials

Cited by 37 publications

References 9 publications

Effects of Deposition Pressure on Properties of Carbon-Doped Silicon Oxide Low Dielectric Constant Films

Effects of Deposition Pressure on Properties of Carbon-Doped Silicon Oxide Low Dielectric Constant Films

Enhancement of moisture resistance of spin-on low-k HSQ films by hot wire generated atomic hydrogen treatment

Modifications of dielectric films induced by plasma ashing processes: Hybrid versus porous SiOCH materials

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