Life cycle assessment of silicon wafer processing for microelectronic chips and solar cells

Schmidt, Mario; Hottenroth, Heidi; Schottler, M.; Fetzer, Gabriele; Schlüter, Birgit

doi:10.1007/s11367-011-0351-1

Cited by 23 publications

(15 citation statements)

References 13 publications

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“…In order to estimate the environmental impact connected to the fabrication process of microsystems, single indicators such as energy consumption of the fabrication of MEMS products of certain complexity, fabrication technology, and application field have been reviewed. 1 Additional data related to the environmental impact of microsystems fabrication can be adopted from the semiconductor industry, 2,3 as fabrication technologies of MEMS and semiconductor manufacturing are similar in terms of basic processes, as well as processing environment (e.g., cleanroom). Reviewing these data, three conclusions can be drawn:…”

Section: Introduction a Novel Microfabrication Methods For Minimamentioning

confidence: 99%

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Introducing natural thermoplastic shellac to microfluidics: A green fabrication method for point-of-care devices

et al. 2016

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We present a sustainable fabrication method for cheap point-of-care microfluidic systems, employing hot embossing of natural shellac as a key feature of an energyefficient fabrication method that exclusively uses renewable materials as consumables. Shellac is a low-cost renewable biomaterial that features medium hydrophilicity (e.g., a water contact angle of ca. 73 ) and a high chemical stability with respect to common solvents such as cyclohexane or toluene, rendering it an interesting candidate for low-cost microfluidics and a competitor to well-known systems such as paperbased or polydimethylsiloxane-based microfluidics. Moreover, its high replication accuracy for small features down to 30 lm lateral feature size and its ability to form smooth surfaces (surface roughness R a ¼ 29 nm) at low embossing temperatures (glass transition temperature T g ¼ 42.2 C) enable energy-efficient hot embossing of microfluidic structures. Proof-of-concept for the implementation of shellac hot embossing as a green fabrication method for microfluidic systems is demonstrated through the successful fabrication of a microfluidic test setup and the assessment of its resource consumption. Published by AIP Publishing. [http://dx

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Section: Introduction a Novel Microfabrication Methods For Minimamentioning

confidence: 99%

“…For example, for the fabrication of logic chips, at least 4 g of toxic substances and 10 g of corrosive substances are generated per cm 2 chip area (data derived from Ref. 3, for more information please refer to the supplementary material of this paper).…”

Section: Introduction a Novel Microfabrication Methods For Minimamentioning

confidence: 99%

Introducing natural thermoplastic shellac to microfluidics: A green fabrication method for point-of-care devices

et al. 2016

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“…CML2002 (Guinée et al, 2001), but also developed new concepts for human toxicity and ecotoxicity (Schmidt et al, 2011). This method can provide both mid-point and endpoint results based on the life cycle inventory (LCI) results.…”

Section: Lca Methodsmentioning

confidence: 99%

Life cycle assessment of structured corrugation SiC-foam packing

Qiao

Hong

et al. 2016

Journal of Cleaner Production

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“…Since the last decade, environmental analysis of microchips has been progressing towards LCA [10]- [11]. However, it is important to keep in mind that main challenges still remain in developing LCA tools to improve data modeling, keep pace with technology changes and handle uncertainty [12]- [13].…”

Section: B Applying Lca To Ic Technologymentioning

confidence: 99%

An eco-design tool for manufacturers of semiconductor technologies: Looking for environmental opportunities in the design phase

Villard

Brissaud

et al. 2012

2012 IEEE International Symposium on Sustainable Systems and Technology (ISSST)

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The paper presents an eco-design methodology, dedicated to semiconductor components manufacturers. This method aims to increase the designers' environmental consciousness and drive them systematically to explore innovative opportunities that can positively impact the environment during the early stages of design phase. The method relies on an original LCA-based tool for the environmental analysis of integrated circuits. It is developed in collaboration with a pilot team so as to help them develop and integrate their own eco-design approach. It allows the designers to acquire basic environmental knowledge and know-how during the analysis phase while ensuring high environmental performances of the microchips. The tool is organized into three main axes: characterizing design decisions in terms of impacts; controlling the evolution of new generations compared to older ones; and finding leverages for improvement. The environmental evaluation of a technology under development was initially assessed but as it is a preliminary work, the results were not directly used to design or redesign this technology. This pilot experiment gave encouraging results and validated the method capable of arousing the designers' interest on the environmental impact of their activity. The interpretation of the results allowed the design team to establish trends and directions for improvement for the future technologies they will design.

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Life cycle assessment of silicon wafer processing for microelectronic chips and solar cells

Cited by 23 publications

References 13 publications

Introducing natural thermoplastic shellac to microfluidics: A green fabrication method for point-of-care devices

Introducing natural thermoplastic shellac to microfluidics: A green fabrication method for point-of-care devices

Life cycle assessment of structured corrugation SiC-foam packing

An eco-design tool for manufacturers of semiconductor technologies: Looking for environmental opportunities in the design phase

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