Fabrication of Long Range Surface Plasmon Polariton Bragg Waveguide Biosensors on Cytop and Multilayer Substrates

Northfield, Howard

doi:10.22215/etd/2015-11156

Cited by 2 publications

(19 citation statements)

References 21 publications

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“…The S-grade was used as an optical cladding material in the previous work [40] [41] [42] [43]. Since the S-grade was not designed for adhesion to metal, an additional diluted M-grade was applied on the top of the cladding to improve adhesion with Au waveguides [44]. However, severe cracking issues were found when spinning the first thinner layer of CYTOP S-grade on top of the lower cladding CYTOP stack, leading to a zero yield of the whole wafer.…”

Section: Lrspp Biosensormentioning

confidence: 99%

“…An additional issue is that M type CYTOP does not exhibit sufficient mechanical stability during wafer dicing [45]. Successful fabrication trials with CYTOP A-grade led to selection of this material for this research as it demonstrated good adhesion to Au waveguides and thickness could be increased through multiple coats without severe cracking issues observed in [44].…”

Section: Lrspp Biosensormentioning

confidence: 99%

“…The other is that Al mask was patterned to replace the photoresist SPR-220 in order to eliminate the photoresist cracking which is believed to result from the soft bake step in patterning SPR-220. Some process modifications based on the previous research [40] [41] [42] [43] [44] are discussed in this chapter as well.…”

Section: Chapter: Fabrication Of Surface Plasmon Biosensor In Cytopmentioning

confidence: 99%

“…The wafer preparation in this process was significantly modified from the previous work in [40] [41] [42] [43] [44] due to the use of CYTOP A-grade, which offered the best adhesion when used in conjunction with the APTES. Previous processes applied a diluted M-grade on the substrate as an adhesion layer, with subsequent S-grade layers used as a cladding dielectric material.…”

Section: Wafer Selection and Preparationmentioning

confidence: 99%

“…The lower CYTOP cladding preparation was adapted with moderate modifications from the previous work [40] [41] [42] [43] [44]. Specifically, there were two modifications involving baking temperature and time.…”

Section: Table I Lower Cytop Cladding Fabrication Processmentioning

confidence: 99%

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Fabrication of Long Range Surface Plasmon Polariton Biosensors Incorporating a Channel Etch Stop Layer and Wafer Bonded Cover

Ren¹

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This thesis presents the micro-fabrication process of a Long Range Surface Plasmon Polariton (LRSPP) biosensor device. The fabrication process was modified in two aspects which include adding a channel etch stop layer to improve the accuracy and uniformity of channels in the device and replacing the photoresist etching mask by an Al etching mask to avoid the thermal cracking. The optical performance of the fabricated chips shows that the biosensor has a 5.03dB/mm attenuation loss and has a 0.10dB response for a monolayer of BSA on Au waveguides. CYTOP bonding process was introduced in the fabrication of the device that incorporates a glass cover. A glass wafer was successfully bonded to a silicon wafer by CYTOP bonding process to seal the channels, which ensured an isolated testing environment for the biochemical fluid.iii

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Section: Lrspp Biosensormentioning

confidence: 99%

Section: Lrspp Biosensormentioning

confidence: 99%

Section: Chapter: Fabrication Of Surface Plasmon Biosensor In Cytopmentioning

confidence: 99%

Section: Wafer Selection and Preparationmentioning

confidence: 99%

Section: Table I Lower Cytop Cladding Fabrication Processmentioning

confidence: 99%

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Fabrication of Long Range Surface Plasmon Polariton Biosensors Incorporating a Channel Etch Stop Layer and Wafer Bonded Cover

Ren¹

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Fabrication of Long Range Surface Plasmon Polariton Biosensors incorporating Optical Waveguides and Encapsulated Microfluidic Channels via Wafer Bonding"

Asif¹

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A microfabricated structure incorporating optical waveguides and closed microfluidic channels is an essential component in realizing a practical long range surface plasmon polariton (LRSPP) biosensor. This has been achieved through advances in fabrication processes to realize reliable optical waveguides, and by development of a reliable wafer bonding process to create closed fluid channels. An existing process for fabrication of gold waveguides was modified by introducing ultra-shallow trenches to recess waveguides and present a planar surface for bonding. An improved fluidic channel etching process was characterized and successfully employed, yielding very smooth channel surfaces free from curtaining and grass issues. Optical performance of the complete bonded chips was demonstrated and verified using a cutback measurement method, producing an attenuation loss of 4.92 dB/mm. An alternative hot embossing process for formation of microfluidic channels on TOPAS substrate was investigated. Embossing die was produced on 4-inch silicon wafer using deep reactive ion etching (DRIE) to create 29 µm raised channels, and the die was subsequently used to transfer the channel structure to the TOPAS material. I would like to thank thesis supervisors Dr. Niall Tait and Dr. Pierre Berini, for providing me an opportunity to work in the area of microfabrication in general, and in particular, optical LRSPP biosensor project. It was a fascinating introduction to the field, and an excellent opportunity to learn from their extensive knowledge and experience. It was a great pleasure to work under their supervision and directions. I acknowledge and thank the Carleton University microfabrication staff, Rob Vandusen, Angela Williams and Rodney Aiton for providing training, consultation, and assistance in fabrication techniques and equipment operations. I also thank the staff at the University of Ottawa fabrication facility, Howard Northfield, Ewa Lisicka-Skrzek, Choloong Hahn, and Anthony Olivieri for their help and assistance in equipment usage and consultation. I extend my appreciation and thank my project colleague, Pengshuai Ren who acted as a close mentor for most of the project. I also thank and acknowledge Alex Krupin, Wei Ru, and Zohreh Hirbodvash for device testing. I acknowledge the assistance, consultation, and support received from Dr. Jeremy Upham and thank him for his contribution. I also appreciate the encouragement and motivation from Muhammad Osama Ali throughout this research work and acknowledge Raheel Ahmed for assistance in drawing the device schematics. Finally, I express deep gratitude to my parents, and my wife Saima and three innocent souls, Usva, Ibrahim and Emama for their continuous support and motivation throughout my studies.

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Fabrication of Long Range Surface Plasmon Polariton Bragg Waveguide Biosensors on Cytop and Multilayer Substrates

Cited by 2 publications

References 21 publications

Fabrication of Long Range Surface Plasmon Polariton Biosensors Incorporating a Channel Etch Stop Layer and Wafer Bonded Cover

Fabrication of Long Range Surface Plasmon Polariton Biosensors Incorporating a Channel Etch Stop Layer and Wafer Bonded Cover

Fabrication of Long Range Surface Plasmon Polariton Biosensors incorporating Optical Waveguides and Encapsulated Microfluidic Channels via Wafer Bonding"

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