The inspirational ideas of Advocate General Francis Jacobs have been drawn together here for the first time in one volume. Fifteen leading EU law practitioners and academics have contributed, including both Sir Francis's predecessor and his successor, covering topics of current discussion in this continually evolving field. Each contributor deals with a discrete topic of EU law and discusses its evolution to date, its current state and its future development, always with specific reference to Sir Francis's opinions. Covering a diverse range of EU law topics, this book will be of great interest to anyone seeking a greater insight into the workings of the European Court of Justice and the role of the Advocate General, and also for anyone involved in the academic study of EU law or practising and litigating in the field. Making Community Law should provide a rich treasury of ideas, explaining both the current state of EU jurisprudence as well as considering the next steps in the making of EU law.

This dissertation provides the first systematic analysis of the dynamic energy efficiency of vertical-cavity surface-emitting lasers (VCSELs) for optical interconnects, a key technology to address the pressing ecological and economic issues of the exponentially growing energy consumption in data centers. Energy-efficient data communication is one of the most important fields in "Green Photonics" enabling higher bit rates at significantly reduced energy consumption per bit. In this thesis the static and dynamic properties of GaAs-based oxide-confined VCSELs emitting at 850 nm and 980 nm are analyzed and general rules for achieving energy-efficient data transmission using VCSELs at any wavelength are derived. These rules are verified in data transmission experiments leading to record energy-efficient data transmission across a wide range of multimode optical fiber distances and at high temperatures up to 85 DegreesC. Important trade-offs between energy efficiency, temperature stability, modulation bandwidth, low current-density operation and other VCSEL properties are revealed and discussed.

This dissertation provides the first systematic analysis of the dynamic energy efficiency of vertical-cavity surface-emitting lasers (VCSELs) for optical interconnects, a key technology to address the pressing ecological and economic issues of the exponentially growing energy consumption in data centers. Energy-efficient data communication is one of the most important fields in "Green Photonics" enabling higher bit rates at significantly reduced energy consumption per bit. In this thesis the static and dynamic properties of GaAs-based oxide-confined VCSELs emitting at 850 nm and 980 nm are analyzed and general rules for achieving energy-efficient data transmission using VCSELs at any wavelength are derived. These rules are verified in data transmission experiments leading to record energy-efficient data transmission across a wide range of multimode optical fiber distances and at high temperatures up to 85 DegreesC. Important trade-offs between energy efficiency, temperature stability, modulation bandwidth, low current-density operation and other VCSEL properties are revealed and discussed.