Abstract
The growing need for classical as well as quantum optical sensing places increasingly stringent requirements upon the desired characteristics of the engendered fields. Specifically, achieving superior field enhancement plays a critical role in applications ranging from chem-bio sensing, Raman and infrared spectroscopies to ion trapping and qubit control in emerging quantum-information science. Due to their low optical losses and ability to exhibit resonant field enhancements, all dielectric multilayers are emerging as an optical material system not only useful to classical photonics and sensing but also of potential to be integrated with quantum materials and quantum sensing. The recently introduced concept of zero-admittance layers [1] within dielectric multilayer materials, enables the creation and control of resonant fields orders of magnitude larger than the exciting field. Here, invoking the zero-admittance concept, we design, fabricate, and characterize an all-dielectric nonabsorbing stack and demonstrate the engendered huge field enhancement. Describing the fields in terms of Bloch surface waves, we connect the surface field to the semiperiodicity in the dielectric domains of the stack. As a specific application of the resonant field, we propose and demonstrate refractive-index sensing for the detection of trace amounts of an analyte. The results include a quantification of the sensitivity of the device with respect to the profile of the exciting field. The experimental results are shown to be in good agreement with theoretical calculations.
Original language | English |
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Article number | 054064 |
Journal | Physical Review Applied |
Volume | 13 |
Issue number | 5 |
DOIs | |
State | Published - May 2020 |
Funding
The authors acknowledge the PSA group for their support through the OpenLab PSA/AMU (Automotive Motion Lab through the StelLab network), the ANRT for their support through the CIFRE program and the RCMO Group of the Institut Fresnel for the realization of the coatings. A.P. acknowledges support from the laboratory directed research and development (LDRD) program at the Oak Ridge National Laboratory (ORNL). This work is also partly supported by a grant from the PROCORE-France/Hong Kong Joint Research Scheme sponsored by the Research Grants Council of Hong Kong and the Consulate General of France in Hong Kong (Reference No. F-CityU108/16).