Laser Systems and Applications

Transcription

1 MSc in Photonics & Europhotonics Laser Systems and Applications Cristina Masoller Research group on Dynamics, Nonlinear Optics and Lasers (DONLL) Departament de Física i Enginyeria Nuclear Universitat Politècnica de Catalunya cristina.masoller@upc.edu

2 Outline Block 1: Low power laser systems Introduction Semiconductor light sources Models Dynamical effects Applications: telecom & datacom, storage, others

3 Semiconductor lasers: types and applications Low-power visible: displays, projectors, imaging, pointers, data storage (CDs, DVDs), etc. Low-power near-infrared: telecom, datacom, sensors, etc. High-power near-infrared: Pumping (fiber lasers, solid-state lasers, amplifiers) Material processing (cutting, soldering) 12/01/2016 3

4 Optical communications No diode laser No internet! Source: Infinera 12/01/2016 4

5 Evolution of the use of diode lasers for optical data storage and communications The use of laser-based CDs, DVDs and Blu-rays is decreasing due to Flash drives, streaming video, the Cloud, and the preference for lightweight portable computers. But the opposite scenario holds for lasers used in datacenters and telecommunications. Recent advances in laser diodes allow Google to build energy efficient, low-cost datacenters. Recent advances in telecom lasers (and advances in signal processing) allow internet providers to upgrade to a new technology: 100 Gbit/s. 12/01/2016 5

6 Wavelengths and applications Short wavelength Non telecommunications Long wavelength Telecommunications Source: SUEMATSU & IGA: SEMICONDUCTOR LASERS IN PHOTONICS, 12/01/ JOURNAL OF LIGHTWAVE TECHNOLOGY, VOL. 26, 1132, 2008

7 Optical communications: a along way from the beginning The first optical transmission system operated over 11 km of fiber at 45 Mbit/s: in May 1977 optical fibers were used to connect three telephone central offices in downtown Chicago. In the late 1970s, indium gallium arsenide phosphide (InGaAsP) lasers operating at longer wavelengths were demonstrated, enabling systems to transmit data at higher speeds and over longer distances. In the 1980s: wavelength-division multiplexing (WDM). A multiplexer at the transmitter is used to join signals together, and a demultiplexer at the receiver, to split them apart. Source: Nature Photonics 4, 287 (2010) 7

8 Wavelength-division multiplexing Channels need to be separated in frequency far enough such that the modulation sidebands of neighboring channels don t overlap. The faster the modulation, the more difficult this becomes. Souce: D. Natelson, Rice University 12/01/2016 8

9 Erbium-doped fiber amplifiers (EDFAs) In the 1990s the development of EDFAs enabled long transmission distances. Diode lasers are efficient pump sources for EDFAs. In 1996: 5 Gbit/s transoceanic systems spanning more than 6,000 km without the need for any optical-to-electronic conversion. By 2010: single fibers that carried signals at hundreds of different wavelengths could transmit terabits/s of information. The rapid growth of Internet traffic, driven by new applications (youtube, skype, etc), the single-fiber bandwidth capacity is rapidly becoming fully utilized. 12/01/2016 Source: Nature Photonics 4, 287 (2010) 9

10 Reaching the fiber capacity limit 12/01/

11 The dispersion problem Modal dispersion arises from differences in propagation times between different modes; it can be avoided by using single-mode fibers. Chromatic dispersion arises from refractive-index variation as a function of wavelength. A fiber's refractive-index profile can be specially tailored to fabricate dispersion-compensating fibers to offset those of standard transmission fibers. Polarization-mode dispersion (PMD) arises from fiber birefringence, which delays one polarization mode with respect to the other. Birefringence in standard transmission fibers is small, so PMD went unnoticed until data rates reached gigabits per second. 11

12 Dispersion management Optical dispersion has been managed by assembling transmission systems from two or more types of fibers with different characteristic dispersion to keep total dispersion low and uniform across the operating wavelengths. That delicate balancing act could manage chromatic dispersion for WDM systems using narrow-linewidth lasers at channel rates of 2.5 or 10 Gbit/s. However, transmitting at higher rates requires much tighter control of chromatic dispersion + management of PMD. Electronic digital signal processing has replaced optics in dispersion management: the replacement of in-line optical dispersion compensation with digital signal processing (DSP) in special-purpose chips has been key to the success of coherent fiber-optic transmission at rates of 100 Gbit/s and up. 12/01/

13 Electronic dispersion compensation Electronic dispersion compensation was first demonstrated in the early 1990s. The compensators used the Viterbi algorithm a standard signalreconstruction technique and application-specific integrated circuits (ASICs) to regenerate the original signal. Nowadays, electronic pre-compensation at the transmitter and postcompensation at the receiver are being used in 40 Gbit/s systems and is replacing optical compensation at 10 Gbit/s. Impressive demonstrations of the hybrid approach (electronics for signal processing and optics for signal transmission): August 2013, Sprint (Overland, KS) and Ciena (Hanover, MD) reported field tests of 400 Gb/s transmission on cables carrying live traffic in Silicon Valley. August 2014: DANTE/Infinera 1Tb/s Budapest-- Bratislava (loopback 510 km). 13

14 VCSELs for communications VCSELs are widely used for optical communications, except for very long distance transmission, where externally modulated DFBs are used to meet requirements of high power and low frequency chirp. VCSELs emitting in the 1310 and 1550 nm bands are used for medium distance communication (metro and access networks, which are based on single-mode optical fibers). Such VCSELs have to be single mode to enable efficient laser fiber coupling and to prevent pulse broadening. VCSEL advantages: high-speed modulation and integration in 1D and 2D arrays 12/01/2016 Source: A. Larsson, JSTQE

15 Source: OPN /01/

16 High speed modulation The maximum single channel (per wavelength) speed is at 10 Gb/s (2011). As the demand for higher data rates increases, 25 Gb/s are required for a 4 25 Gb/s 100G solution. Source: A. Larsson, JSTQE /01/

17 VCSELs in computing: parallel optical links By November 2008, the top 3 supercomputers and the world s first 2 petaflop machines (10 15 FLoating-point Operations Per Second) used VCSEL-based parallel optical links for high speed input/output (I/O) optical links (2.5Gb/s/ch 850nm VCSELs) 12/01/ Source: VCSELS, Editor: R. Michalzik (2013)

18 Evolution of information storage 12/01/

19 Evolution of optical data storage systems First generation (1980s): CDs The information is in a 2D surface of a recording medium and occupies less than 0.01 % of the volume. =780 nm Due to the limitation of the recording wavelength and the numerical aperture (NA) of the recording lens, the storage capacity was MB. 12/01/2016 Source: Optics and Photonics News July/August

20 The following generations Digital versatile disks (DVDs, 1995) Blue DVDs (Blu-rays, 2000) 12/01/2016 Source: Optics and Photonics News July/August

21 What is next in optical data storage? Multi-dimensional systems (via two-photon absorption to decrease depth of field for more layers, or via the polarization of the laser beam), shorter wavelengths (via nonlinear optics: frequency doubling), super-resolution (stimulated emission depletion STED), holographic data storage. 12/01/

22 5D data storage The multiplexed information can be individually addressed by using the appropriate polarization state and wavelength. 12/01/

23 Other applications: sensing, spectroscopy VCSELs typically exhibit an electro-thermal current tuning rate of nm/ma. LI-curve of 1.85 μm VCSEL used for direct absorption measurements. The absorption dips of water vapor are clearly resolved. VCSELs are also popular for energy efficient optical mice. Source: VCSELs, Editor: R. Michalzik (2013) 12/01/

24 From electronics to photonics In electronics: Vacuum tubes Transistor Integrated circuit In photonics: First diode lasers Diode laser Photonic Integrated Circuit (PIC) 12/01/2016 Moving photons, rather than electrons, requires much less power. 24

25 Big data 12/01/2016 Source: OPN set

26 Silicon photonics Silicon is optically transparent at telecom wavelengths (1,310 and 1,550 nm), so it can be used to create waveguides. But silicon lacks the necessary physical properties for active devices: the direct bandgap needed for light emission and the electro-optic effect used for modulation of light. The temperatures at which high-quality GaAs layers grow are so high (700 C) that they damage conventional complementary-metal-oxide-semiconductor (CMOS) chips. 12/01/

27 Source: Intel 12/01/

28 12/01/ Source: Optics and Photonics News, March 2011

29 12/01/

30 The key is monolithic integration: all optical functions on a single chip Arrayed waveguide gratings Source: Infinera, Laser Focus World webcast 12/ /01/

31 Can t we mix InP and Silicon on the chip? Source: Infinera, Laser Focus World webcast 12/ /01/

32 Recent developments A prototype optical microprocessor system was fabricated using standard silicon-based manufacturing methods. The chip integrates 850 photonic components with more than 70 million transistors. The chip contains a dual-core RISC-V microprocessor, 1 MB of random access memory, and electro-optic transmitters and receivers for communications via infrared light signals. OPN online news, december /01/

33 The chip was fabricated using a commercial high-performance 45-nm complementary metal oxide semiconductor (CMOS) silicon-on-insulator (SOI) process. Both the electronic transistors and the optical waveguide cores are located in the same crystalline silicon layer. The microprocessor and memory communicate via photonic signals at 2.5 Gbit/s. The team tested the chip's operation with an external DFB laser operating at 1,183 nm a wavelength to which silicon is transparent. To validate the chip's information-processing functions, the researchers ran several programs on it, including one that rendered the three-dimensional image of a teapot. Possible ways to improve the systems performance : redesigning the modulator to expand bandwidth, improving the receiver's sensitivity operating the laser at the peak-efficiency power level. The experiment was done with much lower laser power due to thermal considerations. 12/01/

34 12/01/

35 Summary Novel semiconductor lasers are nowadays actively being developed to meet the requirements of faster, and more energy-efficient optical communications. A lot of efforts are focused in developing silicon-compatible lasers. Integration is essential. With PICs, microprocessor chips use light, rather than electrons, to move data. This can result in much faster and energy-efficient datacenters and super-computes. 12/01/

36 TF Long-wavelength VCSELs are used for short and medium distance optical communication links. Erbium-doped fiber amplifiers (EDFAs) are routinely used in datacenters and interconnect networks. Narrow-linewidth single-mode lasers allow optical dispersion compensation in transmission channels at rates of 2.5 or 10 Gbit/s. Electronic digital signal processing has replaced optical dispersion compensation in high-rate fiber-optic transmission systems. Increasing the diode laser wavelength increases the capacity of optical storage systems. The high-temperatures required to grow III-V semiconductor materials are the main problem for integrating lasers into silicon chips. 12/01/

37 THANK YOU FOR YOUR ATTENTION! Universitat Politecnica de Catalunya