Quantum Dot Lasers on Silicon: Nonlinear Properties, Dynamics, and Applications (矽基量子點雷射:非線性特性、動態與應用)

Dong, Bozhang

  • 出版商: Springer
  • 出版日期: 2024-02-05
  • 售價: $8,520
  • 貴賓價: 9.5$8,094
  • 語言: 英文
  • 頁數: 189
  • 裝訂: Quality Paper - also called trade paper
  • ISBN: 3031178297
  • ISBN-13: 9783031178290
  • 相關分類: 量子 Quantum
  • 海外代購書籍(需單獨結帳)

相關主題

商品描述

This book provides guidelines and design rules for developing high-performance, low-cost, and energy-efficient quantum-dot (QD) lasers for silicon photonic integrated circuits (PIC), optical frequency comb generation, and quantum information systems. To this end, the nonlinear properties and dynamics of QD lasers on silicon are investigated in depth by both theoretical analysis and experiment.

This book aims at addressing four issues encountered in developing silicon PIC:

1) The instability of laser emission caused by the chip-scale back-reflection. During photonic integration, the chip-scale back-reflection is usually responsible for the generation of severe instability (i.e., coherence collapse) from the on-chip source. As a consequence, the transmission performance of the chip could be largely degraded. To overcome this issue, we investigate the nonlinear properties and dynamics of QD laser on Si in this book to understand how can it be applied to isolator-free photonic integration in which the expensive optical isolator can be avoided. Results show that the QD laser exhibits a high degree of tolerance for chip-scale back-reflections in absence of any instability, which is a promising solution for isolator-free applications.

2) The degradation of laser performance at a high operating temperature. In this era of Internet-of-Thing (IoT), about 40% of energy is consumed for cooling in the data center. In this context, it is important to develop a high-temperature continuous-wave (CW) emitted laser source. In this book, we introduce a single-mode distributed feedback (DFB) QD laser with a design of optical wavelength detuning (OWD). By taking advantage of the OWD technique and the high-performance QD with high thermal stability, all the static and dynamical performances of the QD device are improved when the operating temperature is high. This study paves the way for developing uncooled and isolator-free PIC.

3) The limited phase noise level and optical bandwidth of the laser are the bottlenecks for further increasing the transmission capacity. To improve the transmission capacity and meet the requirement of the next generation of high-speed optical communication, we introduce the QD-based optical frequency comb (OFC) laser in this book. Benefiting from the gain broadening effect and the low-noise properties of QD, the OFC laser is realized with high optical bandwidth and low phase noise. We also provide approaches to further improve the laser performance, including the external optical feedback and the optical injection.

4) Platform with rich optical nonlinearities is highly desired by future integrated quantum technologies. In this book, we investigate the nonlinear properties and four-wave mixing (FWM) of QD laser on Si. This study reveals that the FWM efficiency of QD laser is more than ten times higher than that of quantum-well laser, which gives insight into developing a QD-based silicon platform for quantum states of light generation.

Based on the results in this book, scientists, researchers, and engineers can come up with an informed judgment in utilizing the QD laser for applications ranging from classical silicon PIC to integrated quantum technologies.

商品描述(中文翻譯)

本書提供了開發高性能、低成本和節能的量子點(QD)雷射,用於矽光子集成電路(PIC)、光頻率梳生成和量子信息系統的指南和設計規則。為此,通過理論分析和實驗,深入研究了矽上QD雷射的非線性特性和動力學。

本書旨在解決開發矽PIC時遇到的四個問題:

1)由於芯片尺寸的背向反射引起的雷射發射不穩定性。在光子集成過程中,芯片尺寸的背向反射通常會導致芯片源頭的嚴重不穩定性(即相干崩潰)。因此,芯片的傳輸性能可能會大幅降低。為了解決這個問題,在本書中我們研究了矽上QD雷射的非線性特性和動力學,以了解如何應用於無隔離器光子集成,從而避免使用昂貴的光學隔離器。結果表明,在沒有任何不穩定性的情況下,QD雷射對芯片尺寸的背向反射具有很高的容忍度,這是無隔離器應用的一個有前景的解決方案。

2)在高工作溫度下雷射性能的退化。在物聯網時代,數據中心的冷卻消耗約佔能源的40%。在這種情況下,開發高溫連續波(CW)發射雷射源非常重要。在本書中,我們介紹了一種具有光學波長失調(OWD)設計的單模分佈反饋(DFB)QD雷射。通過利用OWD技術和具有高熱穩定性的高性能QD,當工作溫度較高時,改善了QD器件的所有靜態和動態性能。這項研究為開發無冷卻和無隔離器的PIC鋪平了道路。

3)雷射的有限相位噪聲水平和光學帶寬是進一步提高傳輸容量的瓶頸。為了提高傳輸容量,滿足下一代高速光通信的要求,我們在本書中介紹了基於QD的光頻率梳(OFC)雷射。由於QD的增益展寬效應和低噪聲特性,OFC雷射實現了高光學帶寬和低相位噪聲。我們還提供了進一步改善雷射性能的方法,包括外部光反饋和光注入。

4)未來集成量子技術需要具有豐富光學非線性的平台。在本書中,我們研究了矽上QD雷射的非線性特性和四波混頻(FWM)。這項研究揭示了QD雷射的FWM效率比量子井雷射高出十倍以上,這為開發基於QD的矽平台用於光量子狀態生成提供了見解。

根據本書的結果,科學家、研究人員和工程師可以對使用QD雷射應用於從傳統的矽PIC到集成量子技術的應用做出明智的判斷。

作者簡介

Bozhang Dong received his B.Sc in optoelectronic engineering in 2016 from Huazhong University of Science and Technology, China, and his M.Sc in 2018 from Paris-Saclay University, France. He graduated and received his Ph. D. degree from Institut Polytechnique de Paris, France, in 2021.

Bozhang Dong is now a postdoctoral scholar with the University of California Santa Barbara, USA, working on the development of high-efficiency and low-noise laser sources for silicon photonic integrated circuits. He has been a visiting scholar at National Tsing Hua University, Taiwan. His scientific interests include nonlinear dynamics of semiconductor lasers, optical frequency comb, and optical communication.

作者簡介(中文翻譯)

董博璋於2016年獲得中國華中科技大學光電工程學士學位,並於2018年獲得法國巴黎-索邦大學碩士學位。他於2021年從法國巴黎理工學院獲得博士學位。

董博璋現在是美國加州聖塔芭芭拉大學的博士後研究學者,致力於為矽光子集成電路開發高效率和低噪音的激光光源。他曾在台灣的國立清華大學擔任訪問學者。他的科學興趣包括半導體激光器的非線性動力學、光頻率梳和光通信。