Ultrafast Plasmonic Graphene Photodetector Based on the Channel Photothermoelectric Effect

Gosciniak, Jacek; Rasras, Mahmoud; Khurgin, Jacob B.

doi:10.1021/acsphotonics.9b01585

Cited by 45 publications

(49 citation statements)

References 68 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Here we apply this theory to some recently proposed photodetector structures with the goal of optimizing performances. We start this analysis with our proposed recently bolometric photodetector [34] that is based on the long-range dielectric loaded surface plasmon polariton (LR-DLSPP) waveguide [35,39,43,55,56] with graphene placed at the maximum electric field of the propagating mode ( Fig. 1).…”

Section: Bolometric Photodetector Arrangementmentioning

confidence: 99%

On-Chip Ultrafast Plasmonic Graphene Hot Electron Bolometric Photodetector

Gosciniak¹,

Khurgin

2020

ACS Omega

Self Cite

View full text Add to dashboard Cite

We appraise a waveguide-integrated plasmonic graphene photodetector based on the hot carrier photo-bolometric effect, with performance characterized simultaneously by high responsivity, on the scale of hundreds of A/W, and high speed on the scale of 100's of GHz. Performance evaluation is based on a theory of bolometric effect originating from the band nonparabolicity of graphene. Results compare favorably with the state-of-the-art plasmonic bolometric photodetectors, predicting up to two orders of magnitude increase in a responsivity while keeping speed on the same level, defined by the electron-lattice scattering time in graphene.

show abstract

Section: Bolometric Photodetector Arrangementmentioning

confidence: 99%

On-Chip Ultrafast Plasmonic Graphene Hot Electron Bolometric Photodetector

Gosciniak¹,

Khurgin

2020

ACS Omega

Self Cite

View full text Add to dashboard Cite

show abstract

“…GPDs based on the photothermoelectric (PTE) effect promise large bandwidth, 8 , 22 with the additional advantage of bias-free operation and, thus, zero dark current photovoltage generation. 15 , 23 − 25 The absence of dark current avoids any noise contribution coming from a DC current.…”

mentioning

confidence: 99%

Ultrafast, Zero-Bias, Graphene Photodetectors with Polymeric Gate Dielectric on Passive Photonic Waveguides

et al. 2020

View full text Add to dashboard Cite

We report compact, scalable, high-performance, waveguide integrated graphene-based photodetectors (GPDs) for telecom and datacom applications, not affected by dark current. To exploit the photothermoelectric (PTE) effect, our devices rely on a graphene/polymer/graphene stack with static top split gates. The polymeric dielectric, poly(vinyl alcohol) (PVA), allows us to preserve graphene quality and to generate a controllable p−n junction. Both graphene layers are fabricated using aligned single-crystal graphene arrays grown by chemical vapor deposition. The use of PVA yields a low charge inhomogeneity ∼8 × 10 10 cm −2 at the charge neutrality point, and a large Seebeck coefficient ∼140 μV K −1 , enhancing the PTE effect. Our devices are the fastest GPDs operating with zero dark current, showing a flat frequency response up to 67 GHz without roll-off. This performance is achieved on a passive, low-cost, photonic platform, and does not rely on nanoscale plasmonic structures. This, combined with scalability and ease of integration, makes our GPDs a promising building block for next-generation optical communication devices.

show abstract

“…As reported in [ 107 , 108 ], graphene-based PDs integrated on Si photonic structures have unique properties and advantages such as high responsivity over a broad spectral range and fast operation. Indeed, a recent study shows that the plasmonic graphene PD on the Si waveguide, which relies on the photo-thermo-electric effect with the additional advantage of bias-free operation, has the potential to achieve the optoelectronic bandwidth up to 500 GHz, as shown in Figure 7 c [ 109 ]. As such, the hybrid SOI/graphene platform opens up new opportunities to improve the performance of PDs that are designed to operate at THz frequencies.…”

Section: Silicon Photonics For Thz Techniquesmentioning

confidence: 99%

“…( c ) Schematic of the graphene photodetector with a 500 GHz bandwidth. Reprinted with permission from [ 109 ]. Copyright, American Chemical Society, 2020.…”

Section: Figurementioning

confidence: 99%

A Review on Terahertz Technologies Accelerated by Silicon Photonics

Xie

Zhou

et al. 2021

Nanomaterials

View full text Add to dashboard Cite

In the last couple of decades, terahertz (THz) technologies, which lie in the frequency gap between the infrared and microwaves, have been greatly enhanced and investigated due to possible opportunities in a plethora of THz applications, such as imaging, security, and wireless communications. Photonics has led the way to the generation, modulation, and detection of THz waves such as the photomixing technique. In tandem with these investigations, researchers have been exploring ways to use silicon photonics technologies for THz applications to leverage the cost-effective large-scale fabrication and integration opportunities that it would enable. Although silicon photonics has enabled the implementation of a large number of optical components for practical use, for THz integrated systems, we still face several challenges associated with high-quality hybrid silicon lasers, conversion efficiency, device integration, and fabrication. This paper provides an overview of recent progress in THz technologies based on silicon photonics or hybrid silicon photonics, including THz generation, detection, phase modulation, intensity modulation, and passive components. As silicon-based electronic and photonic circuits are further approaching THz frequencies, one single chip with electronics, photonics, and THz functions seems inevitable, resulting in the ultimate dream of a THz electronic–photonic integrated circuit.

show abstract

Ultrafast Plasmonic Graphene Photodetector Based on the Channel Photothermoelectric Effect

Cited by 45 publications

References 68 publications

On-Chip Ultrafast Plasmonic Graphene Hot Electron Bolometric Photodetector

On-Chip Ultrafast Plasmonic Graphene Hot Electron Bolometric Photodetector

Ultrafast, Zero-Bias, Graphene Photodetectors with Polymeric Gate Dielectric on Passive Photonic Waveguides

A Review on Terahertz Technologies Accelerated by Silicon Photonics

Contact Info

Product

Resources

About