Dr. Hon Ki TSANG
BA, MA(Cantab.), Ph.D., Fellow of IEEE, Fellow
of Optica, Chartered Engineer,
MIET, MHKIE
Wei Lun Professor of Electronic Engineering
Email: hktsang@ee.cuhk.edu.hk
Tsang’s 2 page CV
Tsang's Research Group
(August 2022, photo taken by: Yuanfei Zhang)
Research Interests
Hon Tsang
obtained a PhD from Cambridge University on III-V semiconductor waveguides
devices and their nonlinear optical properties in 1991. He joined CUHK in 1993 and shortly
thereafter branched out into the then
emerging field of silicon photonics. From its small beginnings
attracting interest from only a handful of groups, silicon photonics has grown
in the last 20 years to become a mainstream technology for high
speed energy efficient communications. It is emerging as a key technology for
optical interconnects in data centers, with large volume silicon photonic
products being manufactured by companies such as Intel.
Despite
the commercial silicon photonics transceiver products now being widely
available, silicon photonics still remains a fruitful topic for research
because there remains many important potential future
applications as energy efficient
on-chip optical interconnects in high performance computers, low cost
lab-on-a-chip gas sensors and integrated biosensors, and integrated quantum
photonic devices for quantum computing and quantum communications. Hon Tsang
has made fundamental contributions on the understanding of nonlinear properties
of guided wave optics in silicon waveguides, having carried out some of the
first studies of optical nonlinearities in silicon optical waveguides. As an R&D director in Bookham
Technology plc, in the early 2000s he led the development team for the silicon
waveguide variable optical attenuator arrays which were deployed
commercially in telecommunication networks. Those early silicon photonic products
enabled dynamic balancing of optical power levels during the reconfiguration of
Wavelength Division Multiplexed (WDM) networks.
Hon
Tsang’s research on the inter-relationships between two photon
absorption, free carrier absorption and nonlinear refraction, led to the
experimental realization of high net gain optical amplifiers based on
stimulated Raman scattering in silicon waveguides. These papers are
increasingly relevant in the design of silicon nanophotonic integrated circuits
because the tiny cross-sectional areas of these silicon waveguides enable
nonlinear optical effects such as two photon absorption or self-phase
modulation to manifest at optical powers as low as a few milliwatts. Hon
Tsang’s current research topics include:
·
Subwavelength
gratings for steering, coupling, switching, filtering
light in the spatial, spectral and polarization domains
·
Silicon photonics for
energy efficient terabit/s optical communications
·
Integrated quantum
photonics for quantum imaging
·
Hybrid integration
of 2D materials (such as graphene,
MoS2, WS2 WSe2 , hBN etc) for photodetectors, modulators and nonlinear photonics
·
Integrated photonics
for 3D imaging and optical coherence tomography
Ongoing
Research Grants as Principal Investigator
Title |
Funding
Agency |
Start |
End |
Amount |
Multimode
Waveguide Grating Couplers
(14203620) |
RGC GRF |
|
31/12/2023 |
$845,055 |
Integrated
Spectrometer for Dynamic Optical Coherence Tomography |
ITF |
|
31/12/2023 |
$4,998,739 |
Resonance-Enhanced
Waveguide Grating Couplers for Wideband High Capacity CWDM Transceivers (14207021) |
RGC GRF |
|
31/12/2024 |
$838,393 |
RGC/NSFC Joint Research
Scheme |
01/01/2022 |
31/12/2025 |
$1,171,334 |
|
|
ITF |
01/08/2022 |
31/07/2024 |
$9,839,881 |
|
|
|
|
Description of RGC GRF grants are available from RGC GRF online search
Please email Prof Tsang if you are interested in joining his group as PhD student or postdoctoral fellow. We also have openings for summer research interns. New Postdoctoral fellows can be supported by the ITF Research Talent Hub scheme. Postdoc candidates should have good publication records satisfying the talent hub requirements. Please email Prof. Tsang to inquire about possible new vacancies.
Prof. Tsang has research grants
funding which can support candidates interested in pursuing a PhD in photonics. Please submit your formal
applications to
the Electronic Engineering graduate division and CUHK before 1 December of
each year. Financial support of
graduate students via postgraduate studentship (PGS) of $216300 per year (2020-21 rates). Top
academic track record may qualify
you for nomination to RGC PhD fellowship which has a higher level of financial
support of $26,900 per month
(HKD322,800 per year). Deadline for applications to RGC is 1 December of each
year for admission in August in the next year.
Postdoctoral Researchers: Dr.Yaojing Zhang, Dr.Yi Wang ; Dr. Zunyue Zhang; Dr Hongnan XU
PhD Students: Dan Yi, David Weng U Chan, Gaolei Hu, Jiapeng Luan, Keyi Zhong, Xuetong Zhou, Yue Qin, Shuqi Xiao, Zelu Wang, Chenfei Cui, Liang Zhang, Martin Wing Hei Leung
Recent Alumni: Dr.Rakesh R. KUMAR, Dr Yeyu Yong, Dr Wen Zhou, Dr Xinru
Wu
1. Y. Zhang, K. Zhong, X. Zhou and H.K. Tsang, “Broadband high-Q multimode silicon
concentric racetrack resonators for widely tunable Raman lasers,”. Nat
Commun 13, 3534 (2022).
2.
X. Zhou and H. K. Tsang, "High Efficiency
Multimode Waveguide Grating Coupler for Few-Mode Fibers," in IEEE
Photonics Journal, vol. 14, no. 4,
Art no. 6643405, (2022).
3.
X. Zhou and Hon Ki Tsang, "Optimized shift-pattern overlay for
high coupling efficiency waveguide grating couplers," Opt. Lett. 47,
3968-3971 (2022).
4.
Zunyue Zhang, Yi Wang, Jiarui Wang, Dan Yi, David Weng
U Chan, Wu Yuan, and Hon Ki Tsang, "Integrated scanning
spectrometer with a tunable micro-ring resonator and an arrayed waveguide
grating," Photon. Res. 10, A74-A81 (2022).
5.
Yi Wang, Yaoqiang
Zhou, Zunyue Zhang, Shuqi Xiao, Jian-bin Xu, and Hon Ki Tsang, “40 GHz waveguide-integrated
two-dimensional palladium diselenide photodetectors,”Appl.
Phys. Lett. 120, 231102 (2022).
6.
David W. U Chan, Xiong Wu, Zunyue Zhang,
Chao Lu, Alan Pak Tao Lau, and Hon Ki Tsang, "C-band 67 GHz silicon
photonic microring modulator for dispersion-uncompensated 100 Gbaud
PAM-4," Opt. Lett. 47, 2935-2938 (2022).
7.
Caiming
Sun , B.Li , W.Shi , J.Lin, N.Ding , H.K.Tsang and A.Zhang "Large-Scale
and Broadband Silicon Nitride Optical Phased Arrays," IEEE Journal of
Selected Topics in Quantum Electronics, vol. 28, no. 6, 2022, Art no. 8200710, (2022).
8.
David W.U Chan, G. Zhou, X. Wu, Y. Tong, J. Zhang,
C. Lu, A.P.T. Lau, H.K. Tsang, “A Compact
112-Gbaud PAM-4 Silicon Photonics Transceiver for Short-Reach Interconnects,” Journal of Lightwave
Technology vol. 40, no. 8, pp. 2265-2273, (2022).
9.
Zunyue Zhang, Y. Wang, Jiarui Wang, D. Yi, D. W. U
Chan, W. Yuan, and Hon Ki Tsang, “Integrated scanning spectrometer
with a tunable micro-ring resonator and an arrayed waveguide grating,” Photonics Research (2022).
10.
Dan Yi, X. Wu, H.K. Tsang, “Ultra-Compact
Polarization Analyzer Based on Micro-Ring Resonators,” IEEE Photonics Technology
Letters 33 (24), 1371-1374 (2021).
11.
Dan Yi, Y. Wang, and H. K. Tsang, “Multi-functional
Photonic Processors using Coherent Network of Micro-ring Resonators” APL Photonics 6, article 100801, (2021).
12.
Y. Zhang, K. Zhong, W. Zhou, H.K. Tsang, “Low-Threshold Continuous-Wave Anti-Stokes Raman Lasing in Silicon
Racetrack Resonators” ACS Photonics 8 (12), 3462-3468, (2021).
13.
Y. Zhang, G. Hu, K. Zhong, W.Zhou and H.K. Tsang, "Investigation of low-power
comb generation in silicon microresonators from dual
pumps," Journal of Optics, vol. 23(10), 10LT03 (2021).
14.
Y.
Xue, Y.Han, Y.Tong, Z. Yan, Y. Wang, Z. Zhang, H.K.Tsang and K. M.Lau, "High-performance III-V
photodetectors on a monolithic InP/SOI platform, " Optica vol. 8 pp.1204-09
(2021).
15.
Z. Zhang, Y. Li, Y.Wang, Z.Yu, X. Sun and H.K.Tsang, "Compact High Resolution Speckle Spectrometer by Using Linear Coherent
Integrated Network on Silicon Nitride Platform at 776 nm," Lasers and Photonics Reviews ,
article 2100039 (2021).
16.
B.
Sun, G.Zhou, Y.Wang, X.Xu,
L.Tao,N.Zhao, H.K.Tsang, X.Wang,
Z.Chen, J.B. Xu, "Ultra-Narrowband Photodetector with High Responsivity Enabled by
Integrating Monolayer J-Aggregate Organic Crystal with Graphene," Advanced Optical Materials
vol. 9 article 2100158 (2021).
17.
Z. Zhang, Y. Wang and H. K. Tsang, "Tandem Configuration of Microrings and Arrayed Waveguide Gratings for a
High-Resolution and Broadband Stationary Optical Spectrometer at 860 nm," ACS Photonics vol. 8 pp.
1251-1257 (2021).
18.
Y.
Xue, Yi Wang, W. Luo, J. Huang, L. Lin, H. K.Tsang and K.M. Lau, "Telecom
InP-based quantum dash photodetectors grown on Si" Applied Physics Letters 118,
article 141101 (2021).
19.
Z. Zhang, Y. Tong, Y. Wang
and H. K. Tsang, "Nonparaxial
Mode-size Converter Using an Ultracompact Metamaterial Mikaelian
Lens," Journal of Lightwave
Technology 39, 2077-2083,(2021), doi: 10.1109/JLT.2020.3047118
20.
Y. Wang, Z. Yu, Z. Zhang, X. Sun,
and H.K. Tsang, "Fabrication-Tolerant
and Low-Loss Hybrid Plasmonic Slot Waveguide Mode Converter," Journal of Lightwave Technology 39,
2106-2112, (2021), doi: 10.1109/JLT.2020.3045742.
21.
Yaojing Zhang, Keyi Zhong and H.K. Tsang, “Raman Lasing in
Multimode Silicon Racetrack Resonators,” Lasers & Photonics Reviews 15, 2000336 (2021).
25.
Rakesh Ranjan Kumar and H.K. Tsang, "High-extinction
CROW filters for scalable quantum photonics," Opt. Lett. 46, 134-137 (2021)
28.
Yeyu Tong, Guan-Hong Chen, Yi Wang, Zunyue
Zhang, David Weng U Chan, Chi-Wai Chow
and H.K. Tsang,
"1.12-Tbit/s PAM-4 Enabled by a Silicon Photonic Transmitter Bridged With
a 7-Channel MCF," IEEE Photonics
Technology Letters, 32, 987-990,
(2020).
30.
Y.Tong, W. Zhou, X. Wu and H.K.Tsang,
“Efficient Mode Multiplexer for Few-Mode Fibers Using Integrated
Silicon-on-Insulator Waveguide Grating Coupler” IEEE Journal of Quantum
Electronics 56, 8400107 (2020).
31.
R.R. Kumar, Y.Wang, Y. Zhang, and H.K.
Tsang, “ Quantum States of Higher Order Whispering Gallery Modes in a Silicon
Micro-disk Resonator” Journal of the Optical Society of America B (2020).
32.
Y. Wang, Z. Yu, Y. Tong, B. Sun, Z. Zhang,
J.-B. Xu, X. Sun, and H. K. Tsang, "High-speed
infrared two-dimensional platinum diselenide photodetectors," Applied Physics Letters 116
article 211101(2020).
33.
Z. Zhang, Y. Wang, and H. K. Tsang, "Ultracompact
40-Channel Arrayed Waveguide Grating on Silicon Nitride Platform at 860 nm," IEEE Journal of Quantum
Electronics 56, 8400308 (2020).
34.
Y. Tong, Z. Hu, X. Wu, S. Liu, L. Chang, A.
Netherton, C.-K. Chan, J. E. Bowers, and H. K. Tsang, "An Experimental
Demonstration of 160-Gbit/s PAM-4 Using a Silicon Micro-Ring Modulator," IEEE Photonics Technology
Letters 32, 125–128 (2020).
35.
R. R. Kumar, X. Wu, and H.K. Tsang, "Compact High-Extinction Tunable CROW filters for Integrated Quantum
Photonic Circuits," Optics Letters 45, 1289-1292, (2020).
36.
Y.
Xue, Y. Han, Y. Wang, Z. Zhang, H.K. Tsang, and K. M. Lau, "Bufferless III-V photodetectors directly grown on (001)
silicon-on-insulators," Optics Letters 45 1754-1757 (2020).
37.
W.
Zhou, Y. Tong, X. Sun, and H. K. Tsang, "Ultra-Broadband
Hyperuniform Disordered Silicon Photonic Polarizers," IEEE Journal of Selected
Topics in Quantum Electronics 26, 8200109 (2020).
38.
Y. Zhang, Y. Yao, D. Yi, and H. K.
Tsang, "Radiation pressure and electrostriction induced enhancement for
Kerr-like nonlinearities in a nanoscale silicon pedestal waveguide," Journal of Optics 22,
article 055502 (2020).
39.
Y. Zhang, L. Tao, D. Yi, J.-B. Xu,
and H. K. Tsang, "Enhanced thermo-optic nonlinearities in a MoS2-on-silicon
microring resonator," Applied Physics Express 13, article 002004 (2020).
40.
Y. Zhang, L. Tao, D. Yi, J.-B. Xu,
and H. K. Tsang, "Enhanced four-wave mixing with MoS2 on a silicon waveguide," Journal of Optics 22, article 025503 (2020).
41.
Y.
Wan, S. Zhang, J. C. Norman, M. J. Kennedy, W. He, Y. Tong, C. Shang,
J.-J. He, H. K. Tsang, A. C. Gossard, and J. E. Bowers, "Directly Modulated Single-Mode Tunable Quantum Dot Lasers at 1.3 mm," Laser and Photonics Reviews
14, article 1900348 (2020).
42.
Y.
Wan, J. C. Norman, Y. Tong, M. J. Kennedy, W. He, J. Selvidge, C. Shang,
M. Dumont, A. Malik, H. K. Tsang, A. C. Gossard, and J. E. Bowers, "1.3 mm Quantum Dot-Distributed Feedback Lasers Directly Grown on (001) Si," Laser and Photonics Reviews
14, article 2000037 (2020).
43.
X. Ding, B.P.Yan,
W. Karlen, Y.T. Zhang, H.K. Tsang, "Pulse transit time based respiratory rate estimation with singular
spectrum analysis," Medical & Biological Engineering & Computing 58 (2),
257-266, 2020
44.
Y.
Jiao, J. van der Tol, V. Pogoretskii, J. van Engelen,
A. A. Kashi, S. Reniers, Y. Wang, X. Zhao, W. Yao, T.
Liu, F. Pagliano, A. Fiore, X. Zhang, Z. Cao, R.
R. Kumar, H. K. Tsang, R. van Veldhoven, T. de
Vries, E.-J. Geluk, J. Bolk,
H. Ambrosius, M. Smit, and K. Williams, "Indium Phosphide Membrane Nanophotonic Integrated Circuits on Silicon," Physica
Status Solidi (A) Applications and Materials Science 217, article 1900606 (2020).
45.
Z.
Yu, X. Xi, J. Ma, H. K. Tsang, C.-L. Zou, and X. Sun, "Photonic integrated circuits with bound states in the continuum," Optica 6, pp. 1342-1348 (2019).
46.
Y. Tong, Q. Zhang, X. Wu, C. Shu, and H. K.
Tsang, "112 Gb/s 16-QAM OFDM for 80-km Data Center Interconnects Using
Silicon Photonic Integrated Circuits and Kramers–Kronig
Detection," Journal of Lightwave Technology 37, 3532-3538 (2019).
47.
A.
Jain, N. Hosseinzadeh, X. Wu, H. K. Tsang, R. Helkey, J. E. Bowers, and J. F.
Buckwalter, "A High
Spur-Free Dynamic Range Silicon DC Kerr Ring Modulator for RF Applications," Journal of Lightwave
Technology 37, 3261–3272 (2019).
48.
W.
Zhou, Z. Cheng, X. Chen, K. Xu, X. Sun, and H. Tsang, "Subwavelength
Engineering in Silicon Photonic Devices," IEEE Journal of Selected
Topics in Quantum Electronics 25, article 2900113 (2019).
49.
Y. Tong, C.-W. Chow, G.-H. Chen, C.-W.
Peng, C.-H. Yeh, and H. K. Tsang, "Integrated
Silicon Photonics Remote Radio Frontend (RRF) for Single-Sideband (SSB)
Millimeter-Wave Radio-Over-Fiber (ROF) Systems," IEEE Photonics Journal 11,
7202108 (2019).
50.
H.Wu C. Li, L.Song, H.K. Tsang, J.E. Bowers and D. Dai, "Ultra-Sharp Multimode Waveguide Bends with Subwavelength Gratings," Laser and Photonics Reviews
13, article 1800119 (2019).
51.
B. Zhu, M. Chen, Q. Zhu, G. Zhou, W. Zhou,
N. Zhao, and H. K. Tsang, "Integrated Plasmonic Infrared Photodetector Based on Colloidal HgTe
Quantum Dots," Advanced Materials Technologies 4, 1900354 (2019).
52.
Z.
Yu, Y. Wang, B. Sun, Y. Tong, J.-B. Xu, H. K. Tsang, and X. Sun,
"Hybrid 2D-Material Photonics with Bound States in the Continuum," Advanced Optical Materials
7, article 1901306 (2019).
53.
W. Zhou, and H. K. Tsang, "Dual-wavelength-band subwavelength grating coupler operating in the near
infrared and extended shortwave infrared," Optics Letters 44 3621-3624
(2019).
54.
W. Zhou, Y. Tong, X. Sun, and H. K.
Tsang, "Hyperuniform disordered photonic bandgap polarizers," Journal of Applied Physics
126 article 113106 (2019).
55.
S.
Liu, X. Wu, D. Jung, J. C. Norman, M. J. Kennedy, H. K. Tsang, A. C.
Gossard, and J. E. Bowers, "High-channel-count 20 GHz passively mode-locked quantum dot laser
directly grown on Si with 4.1 Tbit/s transmission capacity," Optica 6, 128-134 (2019).
56.
R. R. Kumar, M. Raevskaia,
V. Pogoretskii, Y. Jiao, and H. K. Tsang, "Entangled photon pair generation from an InP membrane micro-ring resonator," Applied Physics Letters 114
021104 (2019).
57.
Z.
Hu, Y. Shao, X. Ouyang, Y. Tong, J. Zhao, H. K. Tsang, P. D. Townsend,
and C.-K. Chan, "Experimental demonstration of 111.1-Gb/s net information rate using
IM/DD probabilistically shaped orthogonal chirp-division multiplexing with a
10-GHz-class modulator," Optics Express 27 ,33789-33798 (2019).
58.
Y.
Gao, G. Zhou, H. K. Tsang, and C. Shu, "High-speed van der Waals heterostructure tunneling photodiodes
integrated on silicon nitride waveguides," Optica 6, 514-517 (2019).
59.
G.
Chen, C.W. Chow, C.H. Yeh, C.W. Peng, P.C. Guo, J.F. Tsai,M.W.
Cheng, Y. Tong and H. K. Tsang, "Mode-Division-Multiplexing
(MDM) of 9.4-Tbit/s OFDM Signals on Silicon-on-Insulator (SOI) Platform," IEEE Access 7, 129104-129111
(2019).
60.
R. R. Kumar, M. Raevskaia,
V. Pogoretskii, Y. Jiao, and H. K. Tsang, "InP membrane micro-ring resonator for generating heralded single photons," Journal of Optics 21,
115201 (2019).
61.
Y.
Gao, H. K. Tsang, and C. Shu, "A silicon nitride waveguide-integrated chemical vapor deposited graphene
photodetector with 38 GHz bandwidth," Nanoscale 10, 21851-21856
(2018).
62.
Y. Tong, Z. Hu, X. Wu, J. Liu, C.-K.
Chan, C. Shu, and H. K. Tsang, "Negative
Frequency-Chirped 112-Gb/s PAM-4 Using an Integrated Germanium Franz-Keldysh
Modulator," IEEE Photonics Technology Letters 30, 1443-1446 (2018).
63.
Y.Yin, J. Li, H.K. Tsang and D. Dai, "Silicon-graphene photonic devices," Journal of Semiconductors
39, 061009, (2018).
64.
J.
Liu, X. Wu, C. Huang, H. K. Tsang, and C. Shu, "Compensation of
Dispersion-Induced Power Fading in Analog Photonic Links by Gain-Transparent
SBS," IEEE Photonics Technology Letters 30, 688–691 (2018).
65.
Y.
Gao, G. Zhou, N. Zhao, H. K. Tsang and C. Shu, "High-performance chemical vapor deposited graphene-on-silicon nitride
waveguide photodetectors," Optics Letters 43, 1399–1402 (2018).
66.
X. Wu, C. Huang, K. Xu, W. Zhou,
C. Shu, and H. K. Tsang, "3 × 104
Gb/s Single-l Interconnect of Mode-Division Multiplexed Network With a Multicore
Fiber," Journal of Lightwave Technology 36, 318–324 (2018).
67.
D.
Dai, C. Li, S Wang, H. Wu, Y.Shi, Z. Wu, S. Gao, T. Dai,H. Yu
and H.K. Tsang, "10-Channel Mode (de)multiplexer with Dual Polarizations," Laser and Photonics Reviews
12, 1700109 (2018).
68.
W. Zhou, Z. Cheng, X. Sun, and H. K. Tsang,
"Tailorable dual-wavelength-band coupling in a transverse-electric-mode
focusing subwavelength grating coupler," Optics Letters 43, 2985-2988
(2018).
69.
W. Zhou, Z. Cheng, X. Wu, X. Sun, and H. K.
Tsang, "Fully suspended
slot waveguide platform," Journal of Applied Physics 123 063103 (2018)
70.
T.-H.
Xiao, Z. Zhao, W. Zhou, C.-Y. Chang, S. Y. Set, M. Takenaka, H. K.
Tsang, Z. Cheng, and K. Goda, "Mid-infrared high-Q germanium microring resonator," Optics Letters 43, 2885-2888
(2018).
71.
T.-H.
Xiao, Z. Zhao, W. Zhou, M. Takenaka, H. K. Tsang, Z. Cheng, and K. Goda, "High-Q germanium optical nanocavity," Photonics Research 6 925-928
(2018).
72.
Y. Tong, W. Zhou, and H. K. Tsang, "Efficient perfectly vertical grating coupler for multi-core fibers
fabricated with 193 nm DUV lithography," Optics Letters 43 5709-5712 (2018).
73.
Y. Tong, Q. Zhang, X. Wu, C.-W.
Chow, C. Shu, and H. K. Tsang, "Integrated germanium-on-silicon Franz–Keldysh vector modulator
used with a Kramers–Kronig receiver," Optics Letters 43, 4333-4336,
(2018).
74.
Y.
Gao, L. Tao, H. K. Tsang, and C. Shu, "Graphene-on-silicon nitride waveguide photodetector with interdigital
contacts," Applied Physics Letters 112 211107 (2018).
75.
T.
C. Tzu,Y. Hsu, C. Y. Chuang, X. Wu, C. W.
Chow, J. Chen, C. H. Yeh and H. K. Tsang, "Equalization
of PAM-4 Signal Generated by Silicon Microring Modulator for 64-Gbit/s
Transmission," Journal of Lightwave Technology 35, 4943-4948 (2017).
76.
X. Wu, K. Xu, W. Zhou, C. W. Chow,
and H. K. Tsang, "Scalable
Ultra-Wideband Pulse Generation Based on Silicon Photonic Integrated Circuits," IEEE Photonics Technology
Letters 29, 1896–1899 (2017).
77.
Y. Zhang, L. Wang, Z. Cheng, and H. K.
Tsang, "Forward stimulated Brillouin scattering in silicon microring resonators," Applied Physics Letters 111,
041104 (2017).
78.
Y.
Gao, W. Zhou, X. Sun, H. K. Tsang, and C. Shu, "Cavity-enhanced thermo-optic bistability and
hysteresis in a graphene-on-Si_3N_4 ring resonator," Optics Letters 42, 1950-1953
(2017).
79.
W. Zhou, Z. Cheng, X. Wu, B. Zhu,
X. Sun, and H. K. Tsang, "Fully suspended slot waveguides for high refractive index sensitivity," Optics Letters 42,
1245–1248 (2017).
80.
T.-H.
Xiao, Z. Zhao, W. Zhou, M. Takenaka, H. K. Tsang, Z. Cheng, and K. Goda, "Mid-infrared germanium photonic crystal cavity," Optics Letters 42,
2882–2885 (2017).
81.
X. Wu, C. Huang, K. Xu, C. Shu, and H. K.
Tsang, "Mode-Division
Multiplexing for Silicon Photonic Network-on-Chip," Journal of Lightwave
Technology 35, 3223–3228 (2017).
82.
S.
Wang, X. Feng, S. Gao, Y. Shi, T. Dai, H. Yu, H.K. Tsang, and D. Dai, "On-chip reconfigurable optical add-drop multiplexer for hybrid
wavelength/mode-division-multiplexing systems," Optics Letters 42,
2802–2805 (2017).
83.
J.
Kang, Z. Cheng, W. Zhou, T.-H. Xiao, K.-L. Gopalakrisna,
M. Takenaka, H. K. Tsang, and K. Goda, "Focusing subwavelength grating coupler for mid-infrared suspended
membrane germanium waveguides," Optics Letters 42, 2094–2097 (2017).
84.
Z.
Chen, X. Li, J. Wang, L. Tao, M. Long, S.-J. Liang, L. K. Ang, C. Shu, H. K.
Tsang, and J.-B. Xu, "Synergistic Effects of Plasmonics and Electron Trapping in Graphene
Short-Wave Infrared Photodetectors with Ultrahigh Responsivity," ACS Nano 11, 430–437
(2017).
85.
X. Ding, B.P.Yan
Y.T. Zhang, and J. Liu, N. Zhao and H. K. Tsang,, "Pulse Transit Time Based Continuous Cuffless Blood Pressure Estimation:
A New Extension and A Comprehensive Evaluation," Scientific Reports 7, 11554
(2017).