Study of Bragg scattering in the presence of dipole-dipole interaction in plasmonic nanohybrids

IF 2.5 3区 物理与天体物理 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Mahi R. Singh , Xintong Jiang , Sergey Yastrebov
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引用次数: 0

Abstract

We have developed a theory of the Bragg scattering for metallic nanohybrid made of an ensemble of metallic nanorods doped in a substrate. The substrate can gas, liquid or solid. An external laser field is applied to study the Bragg scattered light. The photons from the incident laser interact with the surface plasmons od nanorods and produce surface plasmon polaritons (SPPs). The incident laser field also induced dipoles in the ensemble of nanorods and they interact with each other via the dipole-dipole interaction (DDI). We have developed a theory for Bragg scattering for metallic nanohybrids using the coupled-mode formulism based on Maxwell’s equation in the presence of SPP and DDI fields. It is found that the theory of Bragg scattered depends on the susceptibility induced by the SPP and DDI fields. We used the quantum mechanical density matrix method to calculate the susceptibility. An analytical expression of the Bragg scattered light intensity is obtained. These expressions can be useful for experimental scientists and engineers who can used them to compare their experiments and make new types of plasmonic devices. Next, we have compared our theory with the experiment data for a nanohybrid made of ensemble of Au-nanoris doped in water. We found a good agreement between theory and experiments. We have also performed the numerical simulations to study the effect of SPP and DDI fields on the Bragg intensity. We have predicted an enhancement the Brag intensity due to the SPP and DDI couplings. The enhancement is due to the two extra scattering mechanisms of the SPP and DDI polaritons with acoustic phonons. We have also found that the one peak in the Bragg intensity can be split int many peaks due the SPP coupling, DDI coupling and phase factor. The splitting is due the Bragg factor appearing in the theory, and it includes the coupling of the incident laser, SPP and DDI electric fields with of acoustic phonons. The enhancement effect can be used to fabricate new types of nanosensors. Similarity, splitting phenomenon can be used to fabricate new types nanoswitches where one peak can be considered as the OFF position and many peaks can be considered as the ON position.

等离子纳米混合体中存在偶极-偶极相互作用时的布拉格散射研究
我们提出了由掺杂在基底中的金属纳米棒组成的金属纳米混合体的布拉格散射理论。基底可以是气体、液体或固体。应用外部激光场研究布拉格散射光。入射激光的光子与纳米棒的表面等离子体相互作用,产生表面等离子体极化子(SPP)。入射激光场还会在纳米棒集合体中诱导偶极子,它们通过偶极子-偶极子相互作用(DDI)相互影响。我们以麦克斯韦方程为基础,利用耦合模式公式建立了存在 SPP 和 DDI 场时金属纳米混合物的布拉格散射理论。研究发现,布拉格散射理论取决于 SPP 和 DDI 场引起的感性。我们使用量子力学密度矩阵法计算了感生率。得到了布拉格散射光强度的解析表达式。这些表达式对实验科学家和工程师非常有用,他们可以用它们来比较实验结果,并制造出新型的等离子器件。接下来,我们将我们的理论与在水中掺杂金-硼的纳米混合体的实验数据进行了比较。我们发现理论与实验之间有很好的一致性。我们还进行了数值模拟,以研究 SPP 和 DDI 场对布拉格强度的影响。我们预测 SPP 和 DDI 耦合会增强布拉格强度。这种增强是由于 SPP 和 DDI 极化子与声子的两种额外散射机制造成的。我们还发现,由于 SPP 耦合、DDI 耦合和相位因子的作用,布拉格强度中的一个峰值可以分成多个峰值。这种分裂是由于理论中出现的布拉格因子,它包括入射激光、SPP 和 DDI 电场与声子的耦合。这种增强效应可用于制造新型纳米传感器。与此类似,分裂现象也可用于制造新型纳米开关,其中一个峰值可视为关断位置,多个峰值可视为接通位置。
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来源期刊
CiteScore
5.00
自引率
3.70%
发文量
77
审稿时长
62 days
期刊介绍: This journal establishes a dedicated channel for physicists, material scientists, chemists, engineers and computer scientists who are interested in photonics and nanostructures, and especially in research related to photonic crystals, photonic band gaps and metamaterials. The Journal sheds light on the latest developments in this growing field of science that will see the emergence of faster telecommunications and ultimately computers that use light instead of electrons to connect components.
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