Green Photonics and Electronics

General rules that describe how to achieve extremely energy-efficient data transmission with oxide-confined VCSELs are derived, explained, and verified by data transmission experiments. We demonstrate that VCSELs with smaller oxide-aperture diameters are more energy-efficient than similar VCSELs with larger oxide-aperture diameters and introduce a new method for analyzing the suitability of different VCSELs for application in different optical interconnect configurations by introducing the modulation factor M. Applying the derived rules for energy-efficient VCSEL operation enables record energy-efficient data transmission with less than 100 femto-Joules per bit in a wide range of bit rates and multimode optical fiber lengths.

The rapid growth of internet and cloud computing applications drives a huge demand for bandwidth capacity in communication networks, while power consumption, cost, and space density must scale down. This growth leads to an increase in the size of data centers (longer optical links), and of the fibers’ channel data rate, rooted in Moore’s Law. Until now, multi-mode fibers (MMF) have been largely employed in datacom applications due to the large coupling tolerance. However, the data-carrying capability of MMF decreases with the transmission distance due to pulse broadening resulting from modal and chromatic dispersion. In order to overcome those limits, transceivers based on single mode fiber (SMF) are under development and the first systems are on the market. Vertical-cavity surface-emitting lasers (VCSELs) are the transmitters of choice for short-reach applications due to their low cost, energy efficiency, and small footprint. InP-based VCSELs emitting at long wavelengths (i.e. 1.3 and 1.55 µm) have gained large interest due to their intrinsic lower power consumption (lower band gap) and low losses in silicon waveguides and silica-based optical fibers, which allows longer transmission distances. While short-wavelength GaAs-based VCSELs have achieved small-signal modulation bandwidths up to 30 GHz [1], InP-based VCSELs show inferior modulation capabilities [2, 3]. Up to date, the highest small-signal bandwidth demonstrated on InP-based devices is 22 GHz [3]. The distributed Bragg reflectors (DBRs) commonly used for GaAs-based VCSELs are made of binary and ternary semiconductor compounds, which offer several advantages such as high refractive-index contrast between the layers, good electrical conductivity and low thermal resistivity. The inferiority of semiconductor DBRs lattice matched to InP challenges the modulation bandwidth enhancement of InP-based devices which suffer of poor thermal conductivity, and high lateral spreading resistance. A further challenge is the single-mode laser operation that has motivated the transition from MMF to SMF in datacom systems. In this chapter, the challenges related to InP-based VCSELs are discussed with focus on active region design, cavity engineering, and current and optical confinement. These arguments apply to all InP-based VCSELs with emission wavelength between 1.3 and 2.0 µm. Stationary and dynamic characteristics are presented for a 1.55 µm VCSEL. Finally, datacom and telecom transmission experiments are presented.

Quantum-dot (QD) based semiconductor optical amplifiers (SOAs) are key components for a large number of different applications in particular for all-optical communication networks. They are superior to classical semiconductor amplifiers in many important respects. Multi-wavelength amplification and signal processing at symbol rates larger than 40 GBd and operation in advanced modulation formats is needed in these networks. An introduction into the basics of QD SOAs as well as their key parameters is given at the beginning of this chapter. A novel concept for direct phase modulated signal generation is presented, unique for QD based SOAs. Error-free 25 GBd differential-phase shift keying (DPSK) signal is demonstrated, based there upon. The unique QD properties, i.e. decoupled gain dynamics of the various bound QD states, allows amplifying signals in dual-communication-band configuration both for small and large wavelength differences. Error- and distortion-free amplification of bidirectional 40 GBd on-off keying (OOK) signals, exhibiting a spectral separation of more than 91 nm is presented. Finally, all-optical wavelength conversion (AOWC) of phase-coded signals using four-wave mixing is shown. A guideline for the optimization of the conversion efficiency is given. Eventually error-free 40 GBd differential (quadrature) phase-shift keying (D(Q)PSK) AOWC is demonstrated.

In this chapter optical and electrical properties of quantum-dot mode-locked semiconductor lasers as well as applications based on these devices are discussed. Section 4.1 gives a short overview of different pulse generation and mode-locking techniques, with the main focus on passive mode locking, as well as details on the laser design and advanced features of quantum-dot devices. Timing-jitter reduction and frequency-tuning techniques (hybrid mode locking, optical injection and optical self-feedback) are compared in Sect. 4.2. Section 4.3 is devoted to applications of mode-locked lasers in photonic terahertz signal generation and optical data communication systems.

All-optical processing is based on fast nonlinear effects, such that light can be used to control light. The development of a novel class of low-loss semiconductor optical resonators, capable of field confinement close to the diffraction limit, has decreased the power level required to trigger nonlinear effects by several orders of magnitude. We review a decade of research on all-optical gates aiming both at fast and energy-efficient operation, with the prospect of integration on a silicon photonics platform.

With advances in technology and the expansion of mobile applications, energy consumption, which is one of the fundamental limits in both high performance microprocessors and low to medium performance portable systems.

Energy consumption by data centers is growing at an exponential rate. Similar growth in power consumption had occurred in smaller-scale microprocessor-based computing. In this chapter, the evolution of microprocessor systems is described, highlighting principles and examples of power-saving strategies. The same principles can be applied to large-scale computing centers, in order to address the upcoming power crisis in cloud computing.

Photovoltaics is currently experiencing a rapid global expansion into the Terawatt age, exceeding even the most optimistic predictions of experts just a few years ago. This is driven by innovations, resulting in higher solar energy conversion efficiencies at ever decreasing costs, and the rapidly increasing global market size. This chapter presents a comprehensive discussion of PV technology developments and issues of integration ever increasing amounts of renewable energy into the electricity grid. Based on this we can look forward to establish a reliable, renewables-based energy supply for the world.

In this chapter, we discuss recent advances in novel thin-film photovoltaic devices which allows novel and low-cost applications of photovoltaics. In particular, we discuss organic and perovskite photovoltaics. At the end, we compare the outdoor harvesting efficiency of these novel systems.