Visible-light silicon nitride waveguide devices and implantable neurophotonic probes on thinned 200 mm silicon wafers

Sacher, Wesley D.; Luo, Xianshu; Yang, Yisu; Chen, Fu-Der; Lordello, Thomas; Mak, Jason C. C.; Liu, Xinyu; Hu, Ting; Xue, Tianyuan; Lo, Patrick; Roukes, M. L.; Poon, Joyce K. S.

doi:10.1364/oe.27.037400

Cited by 89 publications

(78 citation statements)

References 25 publications

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“…For example, the sheet density may be increased by integrating multiple photonic layers [40]. Also, the optical transmission of the probes can be increased by roughly an order of magnitude with efficient fiber-to-chip edge couplers [41] and optimized low-loss components; the fiber-to-chip coupling efficiency of the edge couplers in this work was limited to ≈ 14% with optimal alignment [34]. Optimized packaging solutions can also mitigate transmission variations amongst light sheets and improve the thermal stability of the packaged probes.…”

Section: Light-sheet Fluorescence Imagingmentioning

confidence: 96%

“…S1 in the Supplementary Materials. The photonic components were designed for a wavelength of 488 nm to enable excitation of common fluorophores such as green fluorescent protein (GFP) and green calcium dyes; however, these components can also be designed for green, yellow, and red wavelengths, as we show in [34] To rapidly switch between different sheets, we used a spatial addressing approach similar to [35] and as illustrated in Fig. 2(a).…”

Section: A Photonic Neural Probes On 200 MM Silicon Wafersmentioning

confidence: 99%

“…Chemical mechanical planarization (CMP) was used for layer planarization during the fabrication. The fabrication process and waveguide characteristics are described in more detail in [34].…”

Section: Light-sheet Fluorescence Imagingmentioning

confidence: 99%

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Implantable photonic neural probes for light-sheet fluorescence brain imaging

Sacher¹,

Chen²,

Moradi-Chameh³

et al. 2020

Preprint

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Significance: Light-sheet fluorescence microscopy is a powerful technique for high-speed volumetric functional imaging. However, in typical light-sheet microscopes, the illumination and collection optics impose significant constraints upon the imaging of non-transparent brain tissues. Here, we demonstrate that these constraints can be surmounted using a new class of implantable photonic neural probes. Aim: Mass manufacturable, silicon-based light-sheet photonic neural probes can generate planar patterned illumination at arbitrary depths in brain tissues without any additional micro-optic components. Approach: We develop implantable photonic neural probes that generate light sheets in tissue. The probes were fabricated in a photonics foundry on 200 mm diameter silicon wafers. The light sheets were characterized in fluorescein and in free space. The probe-enabled imaging approach was tested in fixed and in vitro mouse brain tissues. Imaging tests were also performed using fluorescent beads suspended in agarose. Results: The probes had 5 to 10 addressable sheets and average sheet thicknesses < 16 μm for propagation distances up to 300 μm in free space. Imaging areas were as large as ≈ 240 μm x 490 μm in brain tissue. Image contrast was enhanced relative to epifluorescence microscopy. Conclusions: The neural probes can lead to new variants of light-sheet fluorescence microscopy for deep brain imaging and experiments in freely-moving animals.

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Section: Light-sheet Fluorescence Imagingmentioning

confidence: 96%

Section: A Photonic Neural Probes On 200 MM Silicon Wafersmentioning

confidence: 99%

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Implantable photonic neural probes for light-sheet fluorescence brain imaging

Sacher¹,

Chen²,

Moradi-Chameh³

et al. 2020

Preprint

Self Cite

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“…This growing interest is moving beyond telecommunication and data center sectors in the infrared wavelength, onto applications such as biosensing, optogenetics, and medical imaging in the visible wavelengths. 1,2 For optogenetics, visible light is used to modulate neurons using light-activated proteins [3][4][5][6] and to expose different engineered cell lines to release therapeutic protein or drugs in vivo. [7][8][9] In addition, visible photonic platform can facilitate lab-on-chip spectroscopy, super-resolution microscopy, miniature endoscopy, and cytometry.…”

Section: Introductionmentioning

confidence: 99%

High coupling efficiency, passive alignment setup for visible-range fiber-to-waveguide edge coupling

et al. 2020

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“…Furthermore, the Si composition can be increased to 4% to shift the entire broad operating range to ~1,300 nm, while Sn can also be alloyed into Ge for an operating coverage beyond 1,700 nm. The mature SiN x -based process 36,37 makes this approach readily accessible in the state-of-the-art foundries. Compared to other Ge strain engineering techniques 38,39,40 , the recessed SiN x stressor maintains both CMOS-compatibility and small device footprint for compact integration.…”

Section: Introductionmentioning

confidence: 99%

Strain-enabled ultra-broadband Ge-based photonic devices for low-cost integration in PICs

Lin

Wen

et al. 2020

Preprint

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Photonic-integrated circuits (PICs) have become one of the most promising solutions to the burgeoning global data communication and are being envisioned to have revolutionary impact in many other emerging fields. This outlook requires future PICs to be significantly more broadband and cost-effective. The current germanium (Ge)-based active photonic devices in PICs are thus facing a new bandwidth-cost trade-off. Here, we demonstrate ultra-broadband, high-efficiency Ge photodetectors up to 1,630 nm operation wavelength and Ge0.99Si0.01 electro-absorption (EA) modulator arrays with an operating range of ~100 nm from 1,525 to 1,620 nm, using a CMOS-compatible recess-type silicon nitride (SiNx) stressor. The broadband operation could facilitate a wide (>100 nm) window for low-cost Ge modulator-detector co-integration, requiring only a single step of Ge epitaxy and two different SiNx depositions. The broad modulation and co-integration coverage can be entirely shifted to shorter (~1,300 nm) and longer (>1,700 nm) wavelengths with small amounts of Si or tin (Sn) alloying. This proof-of-concept work provides a pathway for PICs towards future low-cost and high-data-capacity communication networks, immediately accessible by designers through foundries.

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Visible-light silicon nitride waveguide devices and implantable neurophotonic probes on thinned 200 mm silicon wafers

Cited by 89 publications

References 25 publications

Implantable photonic neural probes for light-sheet fluorescence brain imaging

Implantable photonic neural probes for light-sheet fluorescence brain imaging

High coupling efficiency, passive alignment setup for visible-range fiber-to-waveguide edge coupling

Strain-enabled ultra-broadband Ge-based photonic devices for low-cost integration in PICs

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