Contents The performance of microwave and millimeter-wave photonic systems would benefit from the use of photodiodes (PDs) with high saturation power, high-speed performance, and high responsivity [1], [2]. (a) Cross-sectional view, (b) top view, and (c) conceptual band diagram of the demonstrated NBUTC-PD, which incorporates with an evanescently coupled optical waveguide. In order to meet these three requirements simultaneously, several technologies have been demonstrated, such as evanescently coupled waveguide PDs [3], [4], partially depleted absorber PDs [5], [6], and uni-traveling-carrier PDs (UTC-PDs) [1], [2]. The structure of UTC-PD has attracted much attention due to its excellent speed and output power performance [1]. However, such a device usually suffers from the problem of bandwidth degradation under high dc external bias voltage [7] due to both the high electric field existing at the junction of the collector (C) and photoabsorption (P) layer, and the decrease in the overshoot drift-velocity of photogenerated electrons [7]. One possible way to enhance the speed performance of UTC-PD is to reduce the externally applied bias voltage and let the value of the electric field in the C-P junction approximately for the critical field, which will enhance the drift-velocity of photogenerated electrons [7]. However, under such low reverse bias voltage (around −1 V for 200-nm collector), the field-screening effect, which originates from the difference in polarity between the output ac voltage across the standard 50- load and the dc bias voltage, will seriously limit the maximum output photocurrent of the UTC-PD [7]. In this work, we demonstrate the state-of-the-art performance of a novel photodiode: the near-ballistic UTC-PD (NBUTC-PD). By inserting an additional p+ delta-doped layer in the collector of a traditional UTC-PD, we can achieve near-ballistic transport under high reverse bias voltage (−5 V) and a high output photocurrent (30 mA). The demonstrated novel device has been combined with the evanescently coupled waveguide structure [3], [4] to attain very high responsivity performance.
Abstract:
We demonstrate a novel photodiode at a 1.55-μm wavelength: the near-ballistic uni-traveling-carrier photodiode (UTC-PD). After a p/sup +/ delta-doped layer was inserted i...Show MoreMetadata
Abstract:
We demonstrate a novel photodiode at a 1.55-μm wavelength: the near-ballistic uni-traveling-carrier photodiode (UTC-PD). After a p/sup +/ delta-doped layer was inserted into the collector of a UTC-PD, near-ballistic transport of photogenerated electrons under high reverse bias voltage (-5 V) and a high output photocurrent (/spl sim/30 mA) was observed. The demonstrated device has been combined with an evanescently coupled optical waveguide to attain high responsivity and high saturation power performance. Extremely high responsivity (1.14 A/W), a high electrical bandwidth (around 40 GHz), and a high saturation current-bandwidth product (over 1280 mA/spl middot/GHz, at 40 GHz) with high saturation radio-frequency power (over 12 dBm at 40 GHz) have been achieved simultaneously at a 1.55-μm wavelength.
Published in: IEEE Photonics Technology Letters ( Volume: 17, Issue: 9, September 2005)
Citations are not available for this document.
Cites in Patents (6)Patent Links Provided by 1790 Analytics
1.
Li, Jiang; Vahala, Kerry, "Optical frequency divider based on an electro-optical-modulator frequency comb"
Inventors:
Li, Jiang; Vahala, Kerry
Abstract:
Microwave-frequency signal generation by generating multiple sideband optical signals separated by phase-modulation frequency f(sub)M, generating beat signals between one or two sidebands and one or two optical reference signals, generating a loop-filtered error signal by comparing an electrical reference signal to one of the beat signals or their difference, and controlling with the error signal in a phase-locked loop arrangement a voltage-controlled oscillator (VCO) that drives the sideband generation at the frequency f(sub)M. A portion of the VCO output is the generated microwave-frequency signal.
Assignee:
CALIFORNIA INSTITUTE OF TECHNOLOGY
Filing Date:
25 February 2016
Grant Date:
27 February 2018
Patent Classes:
Current International Class:
H01S0050680000, H01S0050687000, H01S0050000000, H01S0050400000, H01S0050620000, H01S0054000000, H01S0030600000, H01S0031300000, H01S0033000000, H01S0030000000, H03L0070000000, H03B0170000000, H01S0030670000, H01S0032300000
2.
Li, Jiang; Vahala, Kerry, "Stable microwave-frequency source based on cascaded brillouin lasers"
Inventors:
Li, Jiang; Vahala, Kerry
Abstract:
A microwave-frequency source, generating an output electrical signal at an output frequency f(sub)M, comprises a pump laser source, an optical resonator, and a photodetector. Free spectral range v(sub)FSR of the optical resonator equals an integer submultiple of a Brillouin shift frequency v(sub)B of the optical resonator (i.e., v(sub)B=Mv(sub)FSR). The pump laser source is frequency-locked to a corresponding resonant optical mode of the optical resonator. Pumping the optical resonator with output of the pump laser source at a pump frequency v(sub)pump results in stimulated Brillouin laser oscillation in the optical resonator at respective first, second, and third Stokes Brillouin-shifted frequencies v(sub)1=v(sub)pump-v(sub)B, v(sub)2=v(sub)pump-2v(sub)B, and v(sub)3=v(sub)pump-3v(sub)B. The photodetector receives stimulated Brillouin laser outputs at the first and third Stokes Brillouin-shifted frequencies v(sub)1 and v(sub)3 and generates therefrom the output electrical signal at a beat frequency f(sub)M=v(sub)1-v(sub)3=2v(sub)B. The output electrical signal at the output frequency f(sub)M exhibits exceptionally low phase noise.
Assignee:
CALIFORNIA INSTITUTE OF TECHNOLOGY
Filing Date:
06 March 2015
Grant Date:
14 March 2017
Patent Classes:
Current International Class:
H03B0170000000, H01S0033000000, H01S0030670000, H01S0030941000, H01S0031310000, H01S0050000000, H01S0030000000, H01S0030800000
3.
Li, Jiang; Vahala, Kerry, "Dual-frequency optical source"
Inventors:
Li, Jiang; Vahala, Kerry
Abstract:
A dual-frequency optical source comprises: (a) first and second pump laser sources arranged to generate optical pump power at respective first and second pump laser frequencies v(sub)pump1 and v(sub)pump2; and (b) a fiber optical resonator characterized by a Brillouin shift frequency v(sub)B and a free spectral range that is substantially equal to an integer submultiple of the Brillouin shift frequency. Each one of the first and second pump laser sources is frequency-locked to a corresponding resonant optical mode of the fiber optical resonator. First and second optical output signals of the dual-frequency optical reference source at respective first and second output frequencies v(sub)1=v(sub)pump1-v(sub)B and v(sub)2=v(sub)pump2-v(sub)B comprise stimulated Brillouin laser output generated by simultaneous optical pumping of the fiber optical resonator by the first and second pump laser sources, respectively. An output difference frequency v(sub)2-v(sub)1 is greater than about 300 GHz.
Assignee:
CALIFORNIA INSTITUTE OF TECHNOLOGY
Filing Date:
26 January 2015
Grant Date:
03 January 2017
Patent Classes:
Current International Class:
H04B0100000000, H04L0070000000, H04B0102507000, H04B0102575000, H04B0102500000, H04B0105000000, H03L0070800000, H03L0071600000
4.
Li, Jiang; Lee, Hansuek; Chen, Tong; Vahala, Kerry, "Chip-based laser resonator device for highly coherent laser generation"
Inventors:
Li, Jiang; Lee, Hansuek; Chen, Tong; Vahala, Kerry
Abstract:
A highly-coherent chip-based laser generating system includes a disk resonator incorporating a wedge structure fabricated from a silicon dioxide layer of a chip. The disk resonator is operable to generate a highly-coherent laser from a low-coherence optical pump input provided at an optical power level as low as 60 ¿W. The disk resonator is fabricated with sub-micron cavity size control that allows generation of a highly-coherent laser using a controllable Stimulated Brillouin Scattering process that includes matching of a cavity free-spectral-range to a Brillouin shift frequency in silica. While providing several advantages due to fabrication on a chip, the highly-coherent laser produced by the disk resonator may feature a Schawlow-Townes noise level as low as 0.06 Hz(sup)2/Hz (measured with the coherent laser at a power level of about 400 ¿W) and a technical noise that is at least 30 dB lower than the low-coherence optical pump input.
Assignee:
CALIFORNIA INSTITUTE OF TECHNOLOGY
Filing Date:
15 June 2012
Grant Date:
22 March 2016
Patent Classes:
Current International Class:
H01S0051000000, H01S0033000000, H01S0030630000, H01S0030830000, H01S0030940000, H01S0030941000, H01S0031700000
5.
Li, Jiang; Lee, Hansuek; Chen, Tong; Vahala, Kerry, "Chip-based frequency comb generator with microwave repetition rate"
Inventors:
Li, Jiang; Lee, Hansuek; Chen, Tong; Vahala, Kerry
Abstract:
A frequency comb generator fabricated on a chip with elimination of a disadvantageous reflow process, includes an ultra-high Q disk resonator having a waveguide that is a part of a wedge structure fabricated from a silicon dioxide layer of the chip. The disk resonator allows generation of a frequency comb with a mode spacing as low as 2.6 GHz and up to 220 GHz. A surface-loss-limited behavior of the disk resonator decouples a strong dependence of pumping threshold on repetition rate.
Assignee:
CALIFORNIA INSTITUTE OF TECHNOLOGY
Filing Date:
15 June 2012
Grant Date:
23 December 2014
Patent Classes:
Current U.S. Class:
359332000, 385028000, 385030000
Current International Class:
G02F0020200000, G02F0012250000
6.
Vahala, Kerry; Lee, Hansuek; Chen, Tong; Li, Jiang, "Silica-on-silicon waveguides and related fabrication methods"
Inventors:
Vahala, Kerry; Lee, Hansuek; Chen, Tong; Li, Jiang
Abstract:
A method of manufacturing a waveguide eliminates a prior art reflow step and introduces certain new steps that permit fabricating of an ultra-low loss waveguide element on a silicon chip. The ultra-low loss waveguide element may be adapted to fabricate a number of devices, including a wedge resonator and a ultra-low loss optical delay line having an extended waveguide length.
Assignee:
CALIFORNIA INSTITUTE OF TECHNOLOGY
Filing Date:
12 June 2012
Grant Date:
26 August 2014
Patent Classes:
Current U.S. Class:
385014000, 385129000, 438040000, 438043000, 438713000
Current International Class:
G02B0061200000, G02B0061000000, H01L0210000000, H01L0213020000, H01L0214610000, G02B0061360000
