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1. Wavelength Calibration of the Full-sun Ultraviolet Rocket SpecTrograph (FURST)

   Donders, Nicolas; Winebarger, Amy; Kankelborg, Charles; Vigil, Genevieve; Rachmeler, Laurel; Kobayashi, Ken; Zank, Gary (October 2020, Proceedings of the International Astronautical Congress)

   null (Ed.)

   The Sun has a well-known periodicity in sunspot number and magnetic field variation. The underlying cause of this 11-year cycle is not fully understood and has yet to be connected with those processes in other stellar objects. The Full-sun Ultraviolet Rocket SpecTrograph (FURST) is a sounding rocket payload being developed by Montana State University (MSU) alongside the Marshall Space Flight Center (MSFC) solar physics group. Scheduled to launch from White Sands Missile Range (WSMR) in 2022, this instrument is unique in that it will provide the connection between stellar observatories with measurements of our Sun. It will achieve this through measuring high-resolution full-disk spectral irradiance. We aim to obtain a wavelength resolution R > 10,000 in the 120 - 181 nm UltraViolet (UV) range, on par with that of the Hubble (HST) Space Telescope Imaging Spectrograph (STIS). This resolution goal will allow us to study the relatively low-temperature plasma in the chromosphere and lower corona with spectral accuracy down to 0.1 Å (a Doppler-shift of about ± 30 km/s). In addition, the Lyman Alpha (121 nm) line is known to saturate most CCD electronics. These factors illustrate the particular challenge of precise wavelength calibration for this spectral range. We are building a collimator in order to calibrate the FURST instrument under these strict spectral requirements. This paper will present the results of our simulation of the diagnostic lamp signal to be used for wavelength calibration. The simulation allows us to begin to account for photon noise, electronic readout noise, and statistical error. These in turn lead to the development of our pre- and post-launch calibration plans. Future work includes absolute radiometric and wavelength calibration with this new collimator. In addition, the ability of FURST to measure small Doppler-shifts will provide capabilities for planetary atmospheric scientists. This impact is coupled with the diverse international partnership created by the closely-knit Sounding Rocket teams around the globe. Sounding Rockets like FURST have an even broader impact, as they encourage future satellite missions under the prospect of long-term observations. 

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2. Validation of E‐Region Model Electron Density Profiles With AURIC Utilizing High‐Resolution Cross Sections

   https://doi.org/10.1029/2023JA031512  

   Sakib, MD_Nazmus; Soto, Emmaris; Yiğit, Erdal; Evans, J_Scott; Meier, R_R (October 2023, Journal of Geophysical Research: Space Physics)

   Abstract E‐region models have traditionally underestimated the ionospheric electron density. We believe that this deficiency can be remedied by using high‐resolution photoabsorption and photoionization cross sections in the models. Deep dips in the cross sections allow solar radiation to penetrate deeper into the E‐region producing additional ionization. To validate our concept, we perform a study of model electron density profiles (EDPs) calculated using the Atmospheric Ultraviolet Radiance Integrated Code (AURIC; D. Strickland et al., 1999,https://doi.org/10.1016/s0022-4073(98)00098-3) in the E‐region of the terrestrial ionosphere. We compare AURIC model outputs using new high‐resolution photoionization and photoabsorption cross sections, and solar spectral irradiances during low solar activity with incoherent scatter radar (ISR) measurements from the Arecibo and Millstone Hills observatories, Constellation Observing System for Meteorology Ionosphere and Climate (COSMIC‐1) observations, and outputs from empirical models (IRI‐2016 and FIRI‐2018). AURIC results utilizing the new high‐resolution cross sections reveal a significant difference to model outputs calculated with the low‐resolution cross sections currently used. Analysis of AURIC EDPs using the new high‐resolution data indicate fair agreement with ISR measurements obtained at various times at Arecibo but very good agreement with Millstone Hills ISR observations from ∼96–140 km. However, discrepancies in the altitude of the E‐region peak persist. High‐resolution AURIC calculations are in agreement with COSMIC‐1 observations and IRI‐2016 model outputs between ∼105 and 140 km while FIRI‐2018 outputs underestimate the EDP in this region. Overall, AURIC modeling shows increased E‐region electron densities when utilizing high‐resolution cross sections and high‐resolution solar irradiances, and are likely to be the key to resolving the long standing data‐model discrepancies. 

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3. A fiber-optic distributed temperature sensor for continuous in situ profiling up to 2 km beneath constant-altitude scientific balloons

   https://doi.org/10.5194/amt-16-791-2023  

   Goetz, J. Douglas; Kalnajs, Lars E.; Deshler, Terry; Davis, Sean M.; Bramberger, Martina; Alexander, M. Joan (January 2023, Atmospheric Measurement Techniques)

   Abstract. A novel fiber-optic distributed temperature sensing instrument, the Fiber-optic Laser Operated Atmospheric Temperature Sensor (FLOATS), was developed for continuous in situ profiling of the atmosphere up to 2 km below constant-altitude scientific balloons. The temperature-sensingsystem uses a suspended fiber-optic cable and temperature-dependent scattering of pulsed laser light in the Raman regime to retrieve continuous3 m vertical-resolution profiles at a minimum sampling period of 20 s.FLOATS was designed for operation aboard drifting super-pressure balloons inthe tropical tropopause layer at altitudes around 18 km as part of theStratéole 2 campaign. A short test flight of the system was conductedfrom Laramie, Wyoming, in January 2021 to check the optical, electrical, andmechanical systems at altitude and to validate a four-reference temperaturecalibration procedure with a fiber-optic deployment length of 1170 m. During the 4 h flight aboard a vented balloon, FLOATS retrieved temperatureprofiles during ascent and while at a float altitude of about 19 km. TheFLOATS retrievals provided differences of less than 1.0 ∘Ccompared to a commercial radiosonde aboard the flight payload during ascent.At float altitude, a comparison of optical length and GPS position at thebottom of the fiber-optic revealed little to no curvature in the fiber-opticcable, suggesting that the position of any distributed temperaturemeasurement can be effectively modeled. Comparisons of the distributed temperature retrievals to the reference temperature sensors show strongagreement with root-mean-square-error values less than 0.4 ∘C. Theinstrument also demonstrated good agreement with nearby meteorologicalobservations and COSMIC-2 satellite profiles. Observations of temperatureand wind perturbations compared to the nearby radiosounding profiles provide evidence of inertial gravity wave activity during the test flight. Spectral analysis of the observed temperature perturbations shows that FLOATS is an effective and pioneering tool for the investigation of small-scale gravity waves in the upper troposphere and lower stratosphere. 

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4. Field Test of Altitude-Controlled Stratospheric Ozonesonding with Vented Balloons during the 2024 Total Solar Eclipse

   https://doi.org/10.31274/ahac.17935  

   QIU, CHONG; Neumann, Kiefer; Halloran, Aidan; Hibbard, Robert; Babich, Nicolas; Ibrahim, Tarek; Teall, Grace (May 2024, Iowa State University Digital Press)

   The concentration of the stratospheric ozone layer is of great interest to the atmospheric science community, since it is critical in blocking the harmful UV radiation from the sun. Typically, regular weather balloons with Electrochemical Cell (ECC) ozonesondes are used to determine the vertical profile of ozone column concentration within a flight time of ~2 hours, with a limited fraction of the data relevant to the ozone layer. Therefore, it would be ideal if ozonesonde flights can be maintained within the ozone layer (~60,000 to 80,000 ft) to maximize the efficiency in data acquisition, especially considering the rising costs of ozonesonding and high-altitude ballooning. We adapted the vented balloon with altitude-control flight capability from the Nationwide Eclipse Ballooning Program (NEBP) for atmospheric ozonesonding and deployed a commercial ECC ozonesonde payload with this approach from Central Texas during the 2024 total solar eclipse in the hope of (1) field testing the performance and application potential of vented balloons in horizontal ozone layer profiling and (2) monitoring the stratospheric ozone layer during the solar eclipse for an extended period of time. The adapted vent valve successfully lowered the balloon from 71,000 ft to 41,000 ft within minutes and demonstrated promising performance in the field. Unfortunately, unexpected radio communication difficulties were experienced from six hours before the totality to two hours after, leaving the second research objective largely unobtainable. 

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5. Understanding the Variability of Helium Abundance in the Solar Corona Using Three-fluid Modeling and Ultraviolet Observations

   https://doi.org/10.3847/2041-8213/ad5e7e  

   Ofman, Leon; Yogesh; Giordano, Silvio (July 2024, The Astrophysical Journal Letters)

   Abstract The variability of helium abundance in the solar corona and the solar wind is an important signature of solar activity, solar cycle, and solar wind sources, as well as coronal heating processes. Motivated by recently reported remote-sensing UV imaging observations by Helium Resonance Scattering in the Corona and Heliosphere payload sounding rocket of helium abundance in the inner corona on 2009 September 14 near solar minimum, we present the results of the first three-dimensional three-fluid (electrons, protons, and alpha particles) model of tilted coronal streamer belt and slow solar wind that illustrates the various processes leading to helium abundance differentiation and variability. We find good qualitative agreement between the three-fluid model and the coronal helium abundance variability deduced from UV observations of streamers, providing insight on the effects of the physical processes, such as heating, gravitational settling, and interspecies Coulomb friction in the outflowing solar wind that produce the observed features. The study impacts our understanding of the origins of the slow solar wind. 

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