Aleksandrs Leitis

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Based on the ASHRAE Standard 140-2014, this study takes the simulation results of DeST and other simulation software to comprehensively test the accuracy and validity of DeST in calculating building thermal loads and space cooling and heating equipment performance. Special cases were also designed to find out the influencing factors that led to results' differences. It was found that the solar lost through the window, the setting of shading geometry and the mode of inputting surface coefficients can make a big difference to the simulation results. The calculation deviations in most ASHRAE-140 cases are within 10%, which indicate the accuracy of DeST in building energy simulation.

IEEE2021

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Dielectric metasurfaces have emerged as a powerful platform for novel optical biosensors. Due to their low optical loss and strong light-matter interaction, they demonstrate several exotic optical properties, including sharp resonances, strong nearfield enhancements, and the compelling capability to support magnetic modes. They also show advantages such as CMOS-compatible fabrication processes and lower resonance-induced heating compared to their plasmonic counterparts. These unique characteristics are enabling the advancement of cutting-edge sensing techniques for new applications. In this Perspective, we review the recent progress of dielectric metasurface sensors. First, the working mechanisms and properties of dielectric metasurfaces are briefly introduced by highlighting several state-of-the-art examples. Next, we describe the application of dielectric metasurfaces for label-free sensing in three different detection schemes, namely, refractometric sensing, surface-enhanced spectroscopy through Raman scattering and infrared absorption, and chiral sensing. Finally, we provide a perspective for the future directions of this exciting research field.

AMER CHEMICAL SOC2021

Metasurfaces for label-free biosensing mid-infrared optics and active photonic devices

Aleksandrs Leitis

Novel two-dimensional metamaterials, known as metasurfaces, have emerged as a breakthrough platform for controlling electromagnetic wave properties at the nanoscale. These metasurfaces consist of subwavelength nanoantennas or so-called meta-atoms, which can be engineered at will to obtain the desired optical functionalities. The doctoral thesis aims to advance the current state-of-the-art metasurface technology for mid-infrared (mid-IR) applications. The first part of the thesis focuses on surface-enhanced infrared absorption spectroscopy with metasurfaces supporting high-quality (high-Q) resonances. Specifically, it introduces an imaging-based nanophotonic method for detecting mid-infrared molecular fingerprints and its' implementation in chemical identification and compositional analysis of surface-bound analytes. This technique features a two-dimensional pixelated dielectric metasurface with a range of spectrally selective resonances, each tuned to a discrete frequency. The method enables a molecular absorption signature read-out at multiple spectral points and the translation of resulting information into a barcode-like spatial absorption map. Furthermore, the thesis demonstrates high-Q angle-multiplexed metasurfaces, which deliver a large number of on-demand resonances in the mid-IR. This method combines chemically specific broadband IR detection with device-level simplicity and spectrometer-less operation of angle-scanning refractometry. Strikingly, these novel metasurface-based chemical detection methods are capable of resolving absorption fingerprints without the need for spectrometry, thereby paving the way toward sensitive and versatile miniaturized mid-IR spectroscopy devices. Yet another major contribution of the thesis includes a universal method for large-scale nanofabrication of various mid-IR metasurfaces. The core of the approach is based on CMOS-compatible processes where the metasurfaces are fabricated on free-standing metal-oxide membranes. To demonstrate the versatility of our method, we realized metasurfaces for a diverse range of applications in the mid-IR, ranging from highly efficient optical wavefront and polarization control to plasmonic metasurfaces for label-free biochemical detection in aqueous solutions. The membrane-based metasurface concept overcomes the limitations of currently used materials in the mid-IR, therefore enabling mass-production of diverse photonic devices with applications in key areas such as biosensing, optical communications, thermal imaging and spectroscopy. The last chapter of the doctoral thesis shows programmable all-dielectric Huygens' metasurfaces consisting of multi-layer Ge disk meta-units with strategically incorporated nonvolatile phase change material Ge3Sb2Te6. Switching the phase-change material between its' amorphous and crystalline structural states enables nearly full dynamic light phase control with high transmittance in the mid-IR. The versatility of the method is demonstrated by optically programming the spatial light phase distribution of the metasurface with single meta-unit precision and retrieving high-resolution phase-encoded images using hyperspectral measurements. The programmable metasurface concept overcomes the static limitations of previous dielectric metasurfaces and moves the metasurface-based technology one step closer to ultra-compact active optical elements encompassing tunable lenses, dynamic holograms, and solid-state spatial light modulators.

EPFL2021