It takes the average reader 3 hours and 20 minutes to read Chip-scale Plasmonic Resonant Nanostructures by Liang Feng
Assuming a reading speed of 250 words per minute. Learn more
Nanophotonics is finding myriad applications in information technology, health care, lighting and sensing. Plasmonics, as one of the most rapidly growing fields in nanophotonics, has great potential to revolutionize many applications in nanophotonics, including bio-sensing, imaging, lighting, photolithography and magnetic recording. In this dissertation, we explore the electrodynamics of plasmonic fields on different structured metallic chips and demonstrate how to manipulate light from nano to micro scale on the structure plasmonic chips. It is highly desired to excite and control propagation of surface plasmon polariton fields in a systematic fashion as it is possible with optical fields both in free space and dielectric waveguides. To accomplish this goal, we developed the design methodology compatible with the conventional Fourier optical devices, investigated on-chip plasmonic metamaterials with novel material response and functionalities, as well as constructed sophisticated chip-scale integration of different optical element. We begin by discussing the fundamentals of plasmonic fields and modal propagation properties. We next investigate a metallic metamaterial showing form-birefringence by engineering the inherent metal properties on nanoscale, and experimentally characterized their supported plasmonic index ellipsoids. We present novel experimental and analytic results of plasmonic nano metamaterials allowing excitation of plasmonic fields by transverse electric polarized incidence, complementing so far demonstrated transverse magnetic polarized excitation. We further construct a plasmonic photonic crystal to manipulate the propagating plasmonic field on a micro scale. On a lager sub-millimeter scale, we experimentally validated the feasibility of Fourier plasmonics, demonstrating possibilities of miniaturizing the conventional bulky optical devices on small plasmonic chips. We ultimately integrate various photonic components on different scales and provide an approach for efficiently using resonant plasmonic phenomena to achieve nanoscale optical field localization.
Chip-scale Plasmonic Resonant Nanostructures by Liang Feng is 196 pages long, and a total of 50,176 words.
This makes it 66% the length of the average book. It also has 61% more words than the average book.
The average oral reading speed is 183 words per minute. This means it takes 4 hours and 34 minutes to read Chip-scale Plasmonic Resonant Nanostructures aloud.
Chip-scale Plasmonic Resonant Nanostructures is suitable for students ages 12 and up.
Note that there may be other factors that effect this rating besides length that are not factored in on this page. This may include things like complex language or sensitive topics not suitable for students of certain ages.
When deciding what to show young students always use your best judgement and consult a professional.
Chip-scale Plasmonic Resonant Nanostructures by Liang Feng is sold by several retailers and bookshops. However, Read Time works with Amazon to provide an easier way to purchase books.
To buy Chip-scale Plasmonic Resonant Nanostructures by Liang Feng on Amazon click the button below.
Buy Chip-scale Plasmonic Resonant Nanostructures on Amazon