A Fabry-Pérot cavity coupled surface plasmon photodiode for electrical biomolecular sensing

In-situ deciphering the plasmon-boosted gas sensing behavior of orthogonally self-organized 3D cross-stacked Au/WO3 nanowire arrays on microchips

The development of highly sensitive and reliable gas sensors is crucial for environmental monitoring, industrial safety, and healthcare applications. We report a facile block copolymer self-assembly approach for fabricating plasmonic Au nanoparticle-decorated WO3 three-dimensional cross-stacked nanowire arrays on microchips for enhanced gas sensing. The porous nanostructure of 3D WO3 NW framework, coupled with the catalytic and surface plasmon resonance properties of Au NPs, synergistically boosts the NO2 sensing performance. The Au/WO3 sensor exhibits an exceptional response of 340.7 to 50 ppm NO2 at 150 °C in dark conditions, which further increases to 980 under white light illumination, along with rapid response/recovery times, a low detection limit, and excellent stability. To elucidate the gas sensing mechanisms, we employ environmental operando micro-spectroscopy techniques, including conductive atomic force microscopy, Kelvin probe force microscopy, and diffuse reflectance infrared Fourier transform spectroscopy. These advanced characterizations, combined with theoretical calculations, provide direct evidence for the efficient generation and transfer of hot electrons from Au NPs to the WO3 NW matrix under light irradiation, revealing their pivotal role in enhancing NO2 adsorption and expanding the electron depletion layer. In-situ measurements also unveil the dynamic modulation of the Schottky barrier height at the Au/WO3 junction, offering deeper insights into the interplay between environmental factors, hot electrons, and resistance alteration in the metal-semiconductor system. This work provides a promising strategy for designing high-performance gas sensors and paves the way for probing complex gas sensing mechanisms.

S9.6 Antibody-Mediated Wireless Portable Biosensor with Multiple Affinity Enhancements for Comprehensive Detection of Nucleic Acid in Serum

Creating biosensors capable of facilely and entirely excluding the influence of interfering biomolecules in complex samples holds profound significance for advancing detection technology and diagnostics. Here, we develop a wireless portable biosensor (WPB) that prevents interference from abundant biomolecules in serum through homogeneous hybridization and S9.6 antibody-mediated multivalent capture. By transferring the hybridization environment from a heterogeneous chip surface to a homogeneous solution, the biosensor maintains consistent hybridization efficiency in serum as in buffer. Additionally, the use of S9.6 antibody-mediated multivalent capture ensures nearly unchanged binding affinity in serum compared to buffer. On the basis of the multiple affinity enhancements, S9.6 antibody-mediated WPB can achieve ultrasensitive detection of nucleic acid in 50% human serum. Specifically, a subtle blocker is designed to eliminate the competitive monovalent S9.6 antibody-heteroduplex binding, ensuring the efficiency of multivalent S9.6 antibody-heteroduplex interactions. The blocker also enables single-step detection. Moreover, the sensing platform utilizes interferents in serum as in situ antifouling biomolecules to prevent nonspecific adsorption. As a result, the proposed WPB achieves a similar limit of detection for nucleic acids in human serum (95 aM) and in buffer (86 aM). This approach inspires a new idea for complex interference elimination and usage and exhibits comprehensive detection performance in complex samples with potential future diagnostic applications.

Microfluidics and Nanofluidics in Strong Light-Matter Coupling Systems

The combination of micro- or nanofluidics and strong light-matter coupling has gained much interest in the past decade, which has led to the development of advanced systems and devices with numerous potential applications in different fields, such as chemistry, biosensing, and material science. Strong light-matter coupling is achieved by placing a dipole (e.g., an atom or a molecule) into a confined electromagnetic field, with molecular transitions being in resonance with the field and the coupling strength exceeding the average dissipation rate. Despite intense research and encouraging results in this field, some challenges still need to be overcome, related to the fabrication of nano- and microscale optical cavities, stability, scaling up and production, sensitivity, signal-to-noise ratio, and real-time control and monitoring. The goal of this paper is to summarize recent developments in micro- and nanofluidic systems employing strong light-matter coupling. An overview of various methods and techniques used to achieve strong light-matter coupling in micro- or nanofluidic systems is presented, preceded by a brief outline of the fundamentals of strong light-matter coupling and optofluidics operating in the strong coupling regime. The potential applications of these integrated systems in sensing, optofluidics, and quantum technologies are explored. The challenges and prospects in this rapidly developing field are discussed.

Guided wave resonance-based digital holographic microscopy for high-sensitivity monitoring of the refractive index

Surface plasmon resonance holographic microscopy (SPRHM) has been employed to measure the refractive index but whose performance is generally limited by the metallic intrinsic loss. Herein we first, to our knowledge, utilize guided wave resonance (GWR) with low loss to realize the monitoring of the refractive index by integrating with digital holographic microscopy (DHM). By depositing a dielectric layer on a silver film, we observe a typical GWR in the dielectric layer with stronger field enhancement and higher sensitivity to the surrounding refractive index compared to the silver film-supported SPR, which agrees well with calculations. The innovative combination of the GWR and DHM contributes to the highly sensitive dynamic monitoring of the surrounding refractive index variation. Through the measurement with DHM, we found that the GWR presents an excellent sensitivity, which is 2.6 times higher than that of the SPR on the silver film. The results will pave a new pathway for digital holographic interferometry and its applications in environmental and biological detections.

Tailoring Tamm Plasmon Resonances in Dielectric Nanoporous Photonic Crystals

The fields of plasmonics and photonic crystals (PCs) have been combined to generate model light-confining Tamm plasmon (TMM) cavities. This approach effectively overcomes the intrinsic limit of diffraction faced by dielectric cavities and mitigates losses associated with the inherent properties of plasmonic materials. In this study, nanoporous anodic alumina PCs, produced by two-step sinusoidal pulse anodization, are used as a model dielectric platform to establish the methodology for tailoring light confinement through TMM resonances. These model dielectric mirrors feature highly organized nanopores and narrow bandwidth photonic stopbands (PSBs) across different positions of the spectrum. Different types of metallic films (gold, silver, and aluminum) were coated on the top of these model dielectric mirrors. By structuring the features of the plasmonic and photonic components of these hybrid structures, the characteristics of TMM resonances were studied to elucidate effective approaches to optimize the light-confining capability of this hybrid TMM model system. Our findings indicate that the coupling of photonic and plasmonic modes is maximized when the PSB of the model dielectric mirror is broad and located within the midvisible region. It was also found that thicker metal films enhance the quality of the confined light. Gas sensing experiments were performed on optimized TMM systems, and their sensitivity was assessed in real time to demonstrate their applicability. Ag films provide superior performance in achieving the highest sensitivity (S = 0.038 ± 0.001 nm ppm-1) based on specific binding interactions between thiol-containing molecules and metal films.

WS2-Flake-Sandwiched, Au-Nanodisk-Enabled High-Quality Fabry-Pérot Nanoresonators for Photoluminescence Modulation

The increasing demand for compact and high-performance photonic devices drives the development of optical resonators with nanoscale sizes and ultrahigh quality factors. Fabry-Pérot (FP) resonators, the most widely employed optical resonators, can support ultrahigh quality factors in the simple structure, which is particularly attractive for applications in lasers, filters, and ultrasensitive sensors. However, the construction of FP resonators with both nanoscale sizes and high quality factors has still faced challenges. Herein we demonstrate the construction of FP nanoresonators out of single Au nanodisks (NDs) and a Au film, with a WS₂ flake sandwiched in between. The atomically flat surfaces of the WS₂ flake and Au NDs benefit mirror alignment and boost the quality factor up to 76. The nanoresonators can support FP resonances with different mode orders in the visible region. The optical properties and formation mechanisms of the high-quality FP modes are systematically studied. The FP modes are further hybridized with excitons in the WS₂ flake spacer, enabling the modulation of the WS₂ indirect band gap emissions. Our study combines the advantages of plasmonic nanoparticles and FP resonators, providing a promising platform for the development of compact nanophotonic devices such as tunable nanolasers, smart sensors, and photonic-circuit elements.

Fiber SPR two-dimensional micro displacement sensor based on the coaxial double waveguide with a conical structure

Fiber SPR micro displacement sensor cannot be used for two-dimensional displacement sensing at present. In this paper, we proposed and demonstrated a fiber SPR two-dimensional micro displacement sensor based on the coaxial double waveguide with a conical structure. The coaxial double waveguide is fused into a cone as the light injection fiber, and two different forms of outgoing light fields can be obtained through two cores of the fiber. The horn shaped light field emitted by the ring core of the coaxial double waveguide can cooperate with the sensing fiber to realize the micro displacement sensing in the x-axis direction. And the straight beam emitted by the middle core of the coaxial double waveguide can cooperate with the sensing fiber to realize the micro displacement sensing in the y-axis direction. Through simulation analysis and experimental test, its average wavelength sensitivity and light intensity sensitivity of the x-axis displacement are 0.0537nm/µm and 0.000124a.u./µm, respectively. And that of the y-axis displacement are 0.315nm/µm and 0.00277a.u./µm, respectively. The proposed fiber sensor realizes the two-dimensional displacement sensing based on SPR, which can be widely used in the fields of two-dimensional micro displacement measurement and two-dimensional position precision positioning.