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Wastewater Surveillance for SARS-CoV-2 on College Campuses: Initial Efforts, Lessons Learned, and Research Needs
Wastewater surveillance for the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is an emerging approach to help identify the risk of a coronavirus disease (COVID-19) outbreak. This tool can contribute to public health surveillance at both community (wastewater treatment system) and institutional (e.g., colleges, prisons, and nursing homes) scales. This paper explores the successes, challenges, and lessons learned from initial wastewater surveillance efforts at colleges and university systems to inform future research, development and implementation. We present the experiences of 25 college and university systems in the United States that monitored campus wastewater for SARS-CoV-2 during the fall 2020 academic period. We describe the broad range of approaches, findings, resources, and impacts from these initial efforts. These institutions range in size, social and political geographies, and include both public and private institutions. Our analysis suggests that wastewater monitoring at colleges requires consideration of local information needs, sewage infrastructure, resources for sampling and analysis, college and community dynamics, approaches to interpretation and communication of results, and follow-up actions. Most colleges reported that a learning process of experimentation, evaluation, and adaptation was key to progress. This process requires ongoing collaboration among diverse stakeholders including decision-makers, researchers, faculty, facilities staff, students, and community members
The second data release from the European Pulsar Timing Array: IV. Implications for massive black holes, dark matter, and the early Universe
The European Pulsar Timing Array (EPTA) and Indian Pulsar Timing Array (InPTA) collaborations have measured a low-frequency common signal in the combination of their second and first data releases, respectively, with the correlation properties of a gravitational wave background (GWB). Such a signal may have its origin in a number of physical processes including a cosmic population of inspiralling supermassive black hole binaries (SMBHBs); inflation, phase transitions, cosmic strings, and tensor mode generation by the non-linear evolution of scalar perturbations in the early Universe; and oscillations of the Galactic potential in the presence of ultra-light dark matter (ULDM). At the current stage of emerging evidence, it is impossible to discriminate among the different origins. Therefore, for this paper, we consider each process separately, and investigated the implications of the signal under the hypothesis that it is generated by that specific process. We find that the signal is consistent with a cosmic population of inspiralling SMBHBs, and its relatively high amplitude can be used to place constraints on binary merger timescales and the SMBH-host galaxy scaling relations. If this origin is confirmed, this would be the first direct evidence that SMBHBs merge in nature, adding an important observational piece to the puzzle of structure formation and galaxy evolution. As for early Universe processes, the measurement would place tight constraints on the cosmic string tension and on the level of turbulence developed by first-order phase transitions. Other processes would require non-standard scenarios, such as a blue-tilted inflationary spectrum or an excess in the primordial spectrum of scalar perturbations at large wavenumbers. Finally, a ULDM origin of the detected signal is disfavoured, which leads to direct constraints on the abundance of ULDM in our Galaxy
Heat Dissipation of Resonant Absorption in Metal Nanoparticle-Polymer Films Described at Particle Separation Near Resonant Wavelength
Polymer films containing plasmonic nanostructures are of increasing interest for development of responsive energy, sensing, and therapeutic systems. The present work evaluates heat dissipated from power absorbed by resonant gold (Au) nanoparticles (NP) with negligible Rayleigh scattering cross sections randomly dispersed in polydimethylsiloxane (PDMS) films. Finite element analysis (FEA) of heat transport was coordinated with characterization of resonant absorption by Mie theory and coupled dipole approximation (CDA). At AuNP particle separation greater than resonant wavelength, correspondence was observed between measured and CDA-predicted optical absorption and FEA-derived power dissipation. At AuNP particle separation less than resonant wavelength, measured extinction increased relative to predicted values, while FEA-derived power dissipation remained comparable to CDA-predicted power absorption before lagging observed extinguished power at higher AuNP content and resulting particle separation. Effects of isolated particles, for example, scattering, and particle-particle interactions, for example, multiple scattering, aggregation on observed optothermal activity were evaluated. These complementary approaches to distinguish contributions to resonant heat dissipation from isolated particle absorption and interparticle interactions support design and adaptive control of thermoplasmonic materials for a variety of implementations
Heat Dissipation of Resonant Absorption in Metal Nanoparticle-Polymer Films Described at Particle Separation Near Resonant Wavelength
Polymer films containing plasmonic nanostructures are of increasing interest for development of responsive energy, sensing, and therapeutic systems. The present work evaluates heat dissipated from power absorbed by resonant gold (Au) nanoparticles (NP) with negligible Rayleigh scattering cross sections randomly dispersed in polydimethylsiloxane (PDMS) films. Finite element analysis (FEA) of heat transport was coordinated with characterization of resonant absorption by Mie theory and coupled dipole approximation (CDA). At AuNP particle separation greater than resonant wavelength, correspondence was observed between measured and CDA-predicted optical absorption and FEA-derived power dissipation. At AuNP particle separation less than resonant wavelength, measured extinction increased relative to predicted values, while FEA-derived power dissipation remained comparable to CDA-predicted power absorption before lagging observed extinguished power at higher AuNP content and resulting particle separation. Effects of isolated particles, for example, scattering, and particle-particle interactions, for example, multiple scattering, aggregation on observed optothermal activity were evaluated. These complementary approaches to distinguish contributions to resonant heat dissipation from isolated particle absorption and interparticle interactions support design and adaptive control of thermoplasmonic materials for a variety of implementations
Localized plasmonic fields of nanoantennas enhance second harmonic generation from two-dimensional molybdenum disulfide
Frequency-dependence and magnitude of second harmonic generation (SHG) from ~4 Ă— 105 nm2 molybdenum disulfide (MoS2) monolayers was examined in presence of single 150 nm plasmonic gold@silica shell@core nanoantenna monomer and dimers. Quantitative agreement between discrete dipole approximation-calculated fields and measured SHG enhancements was found. SHG from MoS2 was enhanced up to 1.88 Ă— upon deposition of a plasmonic nanoantenna-dimer with 170 nm gap, reaching maximal normalized SHG conversion efficiency of 0.0250%/W. Pump losses attributable to plasmonic damping, e.g., scattering and/or hot-electron injection into MoS2, were apparent. Linear and nonlinear optical activity of MoS2 and nanoantenna controls were compared with literature values
Rate-Limited Electroless Gold Thin Film Growth: A Real-Time Study
Time-resolved,
in situ spectroscopy of electroless (EL) gold (Au)
films combined with electron microscopy showed that the deposition
rate increased up to two-fold on surfaces swept by the bulk flow of
adjacent fluid at Reynolds numbers less than 1.0, compared to batch
immersion. Deposition rates from 5.0 to 9.0 nm/min and thicknesses
of the EL Au film from 20 to 100 nm, respectively, increased predictably
with flow rate at conditions when the deposition was limited primarily
by Fickian diffusion. Time-frames were identified for metal island
nucleation, growth, and subsequent film development during EL Au deposition
by real-time UV–visible spectroscopy of photoluminescence (PL)
and surface plasmon features of nanoscale metal deposits. Film thicknesses
measured by scanning electron microscopy and X-ray photoelectron spectroscopy
paired with real-time optical spectroscopy of kinetic aspects of plasmon
and PL optical features indicated that Au film deposition on surfaces
swept by a steady flow of adjacent fluid can be primarily diffusion
limited
Best Practices and Lessons Learned in Grant Writing for Ag/Applied Economists to Engage in Interdisciplinary Studies
Learning to write successful grant applications takes significant time and effort. This paper presents knowledge, expertise, and strategies from experienced grant applicants and grant officers across several disciplines to support early career scholars and first-time grant writers, with particular guidance for interdisciplinary collaboration. Many Agricultural and Applied Economists are invited to participate in interdisciplinary grant applications. It is important to fully understand the types of projects, nature of collaboration, co-investigators’ characteristics, expected contributions, anticipated benefits, and valuation of collaborative research by one’s peers before initiating new opportunities. Leading and participating in interdisciplinary teams also requires mentorship, patience, professionalism, and excellent communication beyond the scientific merits. This paper shares practical insights to guide scholars through the grant-writing processes beginning with nurturing a mindset, preparing for a consistent work ethic, actively seeking advice, identifying targeted programs, matching a programs’ priorities, a step-by-step framework for team creation and management, effectively managing time and pressure, and transforming failure into success
Polylogarithm-Based Computation of Fano Resonance in Arrayed Dipole Scatterers
Efficient descriptions for Fano resonant
properties of plasmonic
arrays of nanoparticles could support selection of particle and array
characteristics to achieve specific spectral outcomes. In contrast
to conventional particle-by-particle computation of Fano resonances
from arrayed particles, this work uses polylogarithms to assemble
a semianalytical solution to the coupled dipole approximation for
far-field Fano resonances from two-dimensional arrays by superposing
results from discrete, one-dimensional chains of particles that comprise
the array. This approach directly depicts the effects of discrete
particle chains on the overall spectral features of an array, thus
enhancing intuitive understanding of these effects, and reduces the
computation time 56% relative to particle-by-particle evaluation.
Fano resonance spectra calculated using polylogarithms are punctuated
by more frequent, sharper oscillations and fine features due to summed
contributions from distant interfering dipoles not present in spectra
calculated using a necessarily finite number of particles. Chains
more orthogonal to the axis of polarization contribute more Fano features
due to broadband, sin<sup>2</sup> θ<sub><i>ij</i></sub> dependent dipole scattering coupling to narrow diffracted
modes. Overall, the approach improves accessibility and increases
the speed of designing nanoparticle lattices for particular outcomes
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