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1. Markov chain models of emitter activations in single molecule localization microscopy

   https://doi.org/10.1364/OE.530359  

   Sun, Yi (September 2024, Optics Express)

   A well-reasoned model of data movie in single molecule localization microscopy (SMLM) is desired. A model of data movie can be decomposed into a model of emitter activation process and a model of data frame. In this paper, we focus on Markov chain modeling and analyzing of emitter activation process for both cycled and continuous illuminations. First, a two-phase Markov chain is proposed to model the activation process for a pair of conjugated activator and emitter with cycled illumination. By converting the frame-based Markov chain into several cycle-based Markov chains, the stationary state distribution in the photoactivatable period is derived. Further obtained are several formulas that capture the characterization of the two-phase Markov chain. Second, the Markov chain and analytical result are extended to the continuous illumination where an emitter is excited continuously in all frames. Finally, incorporating the model of emitter activation process with our previous model of data frame, the model of data movie for both cycled and continuous illuminations in 3D and 2D imaging are simulated by custom codes. It is shown that the model can synthesize data movies well and the analytical formulas predict the simulation results accurately. The models provide a means to be broadly utilized in generating well-reasoned data movies for training of neural networks and evaluation of localization algorithms. 

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2. Testing Novel New Drip Emitter with Variable Diameters for a Variable Rate Drip Irrigation

   https://doi.org/10.3390/agriculture11020087  

   AL-agele, Hadi A.; Nackley, Lloyd; Higgins, Chad (February 2021, Agriculture)

   null (Ed.)

   This research presents a new variable rate drip irrigation (VRDI) emitter design that can monitor individual water drops. Conventional drip systems cannot monitor the individual water flow rate per emitter. Application uniformity for conventional drip emitters can be decreased by clogged emitters, irregular emitter orifices, and decreases in pressure. A VRDI emitter can overcome the irrigation challenges in the field by increasing water application uniformity for each plant and reducing water losses. Flow rate is affected by the diameter of the delivery pipe and the pressure of the irrigation delivery system. This study compares the volumetric water flow rate for conventional drip emitters and new VRDI emitters with variable diameters inner (1 mm, 1.2 mm, 1.4 mm, and 1.6 mm) and outside (3 mm, 3.5 mm, 4 mm, and 4.5 mm) with three pressures (34 kPa, 69 kPa, and 103 kPa). The tests revealed that the new VRDI emitter had flow rates that increased as the operating pressure increased similar to a conventional drip tube. The flow rate was slightly increased in the VRDI with pressure, but even this increase did not show large changes in the flow rate. The flow rate of the conventional drip tube was 88% larger than the VRDI emitter for all pressures (p < 0.05). However, operating pressure did not affect the drop sizes at the VRDI emitter, but the generalized linear mixed models (GLM) results show that volume per drop was impacted by the outside diameter of the VRDI outlet (p < 0.05). The interaction between the inner and outside diameter was also significant at p < 0.01, and the interaction between outside diameter and pressure was statistically significant at p < 0.01. The electronic components used to control our VRDI emitter are readily compatible with off-the-shelf data telemetry solutions; thus, each emitter could be controlled remotely and relay data to a centralized data repository or decision-maker, and a plurality of these emitters could be used to enable full-field scale VRDI. 

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3. Large-area 1D selective emitter for thermophotovoltaic applications in the mid-infrared

   https://doi.org/10.1116/6.0002198  

   Oh, Minsu; Grossklaus, Kevin; Vandervelde, Thomas_E (December 2022, Journal of Vacuum Science & Technology B)

   Two- or three-dimensionally patterned subwavelength structures, also known as metamaterials, have the advantage of arbitrarily engineerable optical properties. In thermophotovoltaic (TPV) applications, metamaterials are commonly used to optimize the emitter’s radiation spectrum for various source temperatures. The output power of a TPV device is proportional to the photon flux, which is proportional to the emitter size. However, using 2D or 3D metamaterials imposes challenges to realizing large emitters since fabricating their subwavelength features typically involves complicated fabrication processes and is highly time-consuming. In this work, we demonstrate a large-area (78 cm2) thermal emitter. This emitter is simply fabricated with one-dimensional layers of silicon (Si) and chromium (Cr), and therefore, it can be easily scaled up to even larger sizes. The emissivity spectrum of the emitter is measured at 802 K, targeting an emission peak in the mid-infrared. The emissivity peak is ∼0.84 at the wavelength of 3.75 μm with a 1.2 μm bandwidth. Moreover, the emission spectrum of our emitter can be tailored for various source temperatures by changing the Si thickness. Therefore, the results of this work can lead to enabling TPV applications with higher output power and lower fabrication cost. 

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4. Effect of emitter orientation on the outcoupling efficiency of perovskite light-emitting diodes

   https://doi.org/10.1364/OL.400814  

   Zou, Chen; Lin, Lih_Y (August 2020, Optics Letters)

   Metal halide perovskite light-emitting diodes (PeLEDs) have experienced a rapid advancement in the last several years with the external quantum efficiencies (EQEs) reaching over 20%, comparable to the state-of-the-art organic LEDs and quantum dot LEDs. The photoluminescence quantum yields of perovskite films have also been approaching 100%. Therefore, the next step to improving the EQE of PeLEDs should be focused on boosting light extraction. In this Letter, we demonstrate the emitter dipole orientation as a key parameter in determining the outcoupling efficiency of PeLEDs. We find that the ${\mathrm{C}\mathrm{s}\mathrm{P}\mathrm{b}\mathrm{B}\mathrm{r}}_3$emitter has a slightly preferred orientation with the horizontal-to-vertical dipole ratio of 0.41:0.59, as compared to 0.33:0.67 in the isotropic case. A theoretical analysis predicts that a purely anisotropic perovskite emitter may result in a maximum EQE of 36%. 

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5. Distortion of the local density of states in a plasmonic cavity by a quantum emitter

   https://doi.org/10.1088/1367-2630/ac0199  

   Cuartero-González, Alvaro; Manjavacas, Alejandro; Fernández-Domínguez, Antonio I (July 2021, New Journal of Physics)

   Abstract We investigate how the local density of states in a plasmonic cavity changes due to the presence of a distorting quantum emitter. To this end, we use first-order scattering theory involving electromagnetic Green’s function tensors for the bare cavity connecting the positions of the emitter that distorts the density of states and the one that probes it. The confined, quasistatic character of the plasmonic modes enables us to write the density of states as a Lorentzian sum. This way, we identify three different mechanisms behind the asymmetric spectral features emerging due to the emitter distortion: the modification of the plasmonic coupling to the probing emitter, the emergence of modal-like quadratic contributions and the absorption by the distorting emitter. We apply our theory to the study of two different systems (nanoparticle-on-mirror and asymmetric bow-tie-like geometries) to show the generality of our approach, whose validity is tested against numerical simulations. Finally, we provide an interpretation of our results in terms of a Hamiltonian model describing the distorted cavity. 

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