Light-Matter Interactions in Photonic Crystals

光子晶体中的光与物质相互作用

• 批准号: RGPIN-2014-05045
• 负责人: John, Sajeev
• 金额: $ 8.23万
• 依托单位: University of Toronto
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2017
• 资助国家: 加拿大
• 起止时间: 2017-01-01 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=633248
• 关键词: Light; Matter; Interactions; Photonic; Crystals

We propose to study novel and fundamental light-matter interactions in photonic crystals and related nano-structures. The novelty of these materials results from their ability to trap light in unique ways and to engineer ultra-strong coupling between photons and resonant electronic excitations in matter. We propose to elucidate the practical applications of these materials to solar energy harvesting, optical information processing, novel light sources, and optical bio-sensing. We will work closely with leading experimental and nano-fabrication groups to realize the predictions of our theoretical and numerical modeling. We propose to develop thin-film photonic crystal architectures for light trapping, absorption and solar spectral reshaping in next generation photovoltaics. Our effort will focus on the computational design, synthesis, and optical testing of photonic architectures that alter fundamental photon-matter interactions at sub-wavelength scales. The designed architectures offer new paradigms to control, trap, and convert solar energy and to compress the frequency bandwidth of sunlight within the solar cell. The underlying physics of our enhanced light trapping and solar absorption is the through the coupling of sunlight to slow-light modes of the photonic crystal that propagate in directions transverse to the thin-film surface. This corresponds to a spectral range where the photonic density of states is enhanced relative to that of a homogeneous material. Our approach involves the integration of graded anti-reflection architectures with photonic crystal based light-trapping and absorption. This enables light absorption in thin-film (< 500 nanometer) solar cells to rival that of thick (~300 micron) cells and to surpass previously suggested statistical ray trapping limits. Strong light concentration by the photonic crystal, augmented by plasmonic resonances near the back mirror, at frequencies below the solar cell electronic band gap enable nonlinear up-conversion of photons. This spectral compression of the solar spectrum paves the way to solar-to-electricity power conversion efficiency by single junction silicon solar cells exceeding 30%. The role of random structural disorder in the photonic crystal solar cells and its influence on overall solar power conversion efficiency will be investigated. We propose to study a new route to the realization of excitonic coherence and Bose-Einstein condensation at or near room temperature in GaAs multiple quantum well (QW) structures. This involves a new type of quantum cavity enabled by a 3D photonic band gap (PBG) material. The essential scientific advance in this proposal rests on two unique and fundamental properties of PBG materials: (i) By inhibiting radiative recombination of excitons over a specific range of frequencies, it is possible to extend the exciton lifetime well beyond the time scale required to establish thermodynamic equilibrium in a trapped exciton gas. (ii) 3D PBG materials enable stronger, sub-wavelength confinement and focusing of light (without loss), thereby leading to much stronger exciton-photon coupling than achievable with previously studied 1D optical cavities. We will study the nature of quantum many-body correlations in the excitonic Bose condensate and consider the nature of laser-like light emission as the condensate decays radiatively. We propose to design structures that enable ultra-strong coupling between excitons and photons such that equilibrium Bose condensation temperature approaches room temperature. We will work closely with fabrication groups that can synthesize our designed photonic crystal architectures and with experimental optics groups with experience in characterizing excitonic condensates.

我们建议在光子晶体和相关纳米结构中研究新的和基本的光-物质相互作用。这些材料的新颖之处在于它们能够以独特的方式捕获光，并在光子和物质中的共振电子激发之间设计出超强的耦合。我们建议阐明这些材料在太阳能收集、光学信息处理、新型光源和光学生物传感等方面的实际应用。我们将与领先的实验和纳米制造小组密切合作，以实现我们的理论和数值模拟的预测。我们建议开发薄膜光子晶体结构，用于光捕获，吸收和下一代光伏的太阳光谱重塑。我们的工作将集中在光子结构的计算设计、合成和光学测试上，这些结构可以在亚波长尺度上改变光子与物质的基本相互作用。设计的架构提供了新的范例来控制、捕获和转换太阳能，并压缩太阳能电池内的阳光频率带宽。我们增强的光捕获和太阳吸收的基本物理原理是通过阳光与光子晶体的慢光模式的耦合，这些模式沿横向方向传播到薄膜表面。这对应于一个光谱范围，其中状态的光子密度相对于均匀材料的光子密度增强。我们的方法涉及到基于光子晶体的光捕获和吸收的梯度抗反射结构的集成。这使得薄膜（< 500纳米）太阳能电池的光吸收可以与厚（~300微米）电池相媲美，并超过先前建议的统计射线捕获限制。在低于太阳能电池电子带隙的频率下，光子晶体的强光集中，由后镜附近的等离子共振增强，使光子非线性上转换成为可能。这种对太阳光谱的压缩为单结硅太阳能电池的太阳能-电能转换效率超过30%铺平了道路。本文将研究光子晶体太阳能电池中无序结构的作用及其对整体太阳能转换效率的影响。我们提出在GaAs多量子阱（QW）结构中研究在室温或近室温下实现激子相干性和玻色-爱因斯坦凝聚的新途径。这涉及到一种由三维光子带隙（PBG）材料实现的新型量子腔。本提案的重要科学进展取决于PBG材料的两个独特和基本特性：(i)通过抑制激子在特定频率范围内的辐射重组，可以延长激子寿命，远远超过在捕获激子气体中建立热力学平衡所需的时间尺度。（ii） 3D PBG材料能够实现更强的亚波长约束和光聚焦（没有损失），从而导致比以前研究的1D光学腔更强的激子-光子耦合。我们将研究激子玻色凝聚体中量子多体相关的性质，并考虑当凝聚体辐射衰减时类激光光发射的性质。我们建议设计结构，使激子和光子之间的超强耦合，使平衡玻色凝聚温度接近室温。我们将与能够合成我们设计的光子晶体结构的制造团队以及在表征激子凝聚体方面有经验的实验光学团队密切合作。