Polariton

Polariton-This chapter introduces the concept of polaritons—quasiparticles formed from the coupling of photons and excitons—fundamental to the understanding of the plasmonic motor at the nanoscale

Multiple exciton generation-Exploring the mechanism of multiple exciton generation, this chapter explains its importance in enhancing the efficiency of optoelectronic devices, a key area in the nanoscale plasmonic realm

Roton-A roton is discussed as a quasiparticle exhibiting interesting quantum properties, influencing the development of superfluid and condensed matter systems in nanoscale plasmonic applications

Quasiparticle-This chapter provides an overview of quasiparticles—an essential concept in condensed matter physics—exploring how they contribute to the behavior of nanostructures used in plasmonic motors

Magnon-The behavior of magnons, which are collective excitations of spin systems, is examined in the context of their potential to impact the operation of nanoscale devices like polaritons

Excitonpolariton-This chapter looks at the hybridization of excitons and polaritons, a process that forms the foundation for understanding the behavior of materials used in plasmonic systems

Yoshihisa Yamamoto (scientist)-This section focuses on the pioneering work of Yoshihisa Yamamoto in the study of quantum optics and polariton physics, linking his contributions to the broader field of nanoscale plasmonics

Polariton laser-Discussing the concept of polariton lasers, this chapter highlights their potential for creating more efficient lasers, an essential advancement in the field of nanophotonics

Davydov soliton-This chapter introduces Davydov solitons, solutions to nonlinear equations that describe energy transport, with significant applications in the control of polaritons in nanoscale systems

Dressed particle-The concept of dressed particles is explained, where an electron's interaction with its environment alters its effective properties, crucial for understanding polaritons in nanostructured materials

Polariton superfluid-Examining the fascinating behavior of polariton superfluids, this chapter explores their potential applications in creating innovative nanoscale systems for energyefficient devices

Solomon Pekar-This chapter delves into Solomon Pekar's work on the theory of polarons, offering insights into the role of quasiparticles in the development of nanoscale plasmonic technologies

Trion (physics)-The trion, a threeparticle complex, is explored here in terms of its influence on the behavior of excitons and polaritons within nanoscale plasmonic systems

Electrononhelium qubit-This chapter investigates the potential of electrononhelium qubits for quantum computing, a key technology for the future of plasmonic motors and related applications

Polaron-The concept of the polaron is examined in detail, discussing how the coupling of an electron with its surrounding lattice influences its behavior and its application to nanoscale systems

Bose–Einstein condensation of polaritons-This chapter discusses the conditions under which polaritons undergo BoseEinstein condensation, a key phenomenon for understanding superfluidlike behavior in nanoscale systems

Plasmon-The plasmon is introduced as a collective excitation of freeelectron systems, central to the operation of plasmonic motors and the manipulation of light at the nanoscale

Phonon polariton-The interaction between phonons and polaritons is explored, explaining how this coupling influences the thermal and optical properties of nanoscale materials

Bose–Einstein condensation of quasiparticles-A deep dive into the role of quasiparticles in the BoseEinstein condensation process, an important concept in the development of quantum technologies for plasmonic systems