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1

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A. L. Hughes to F. O. Schmitt, May 3, 1941 (2015)

A. L. Hughes

Marine Biological Laboratory Archives (Woods Hole, Mass.)

In: Viktor Hamburger collection, Box 2, Folder 35, Marine Biological Laboratory Archives

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Publication Date: 2023-01-12

Description: Part of To Francis Otto Schmitt from The Schmitty Verein, May 1941

Description: Correspondence

Keywords: People

Repository Name: Woods Hole Open Access Server

Language: English

Type: Text

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2

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Arthur Hughes to Viktor Hamburger, May 23, 1969 (2015)

Hughes, Arthur

Marine Biological Laboratory (Woods Hole, Mass.)

In: Viktor Hamburger Papers, Box 1, Folder 34

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Publication Date: 2023-01-12

Description: Handwritten letter, 1 page

Description: Work of graduate student

Description: Correspondence

Keywords: People

Repository Name: Woods Hole Open Access Server

Language: English

Type: Text

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3

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Arthur Hughes to Viktor Hamburger, October 27, 1965 (2015)

Hughes, Arthur

Marine Biological Laboratory (Woods Hole, Mass.)

In: Viktor Hamburger Papers, Box 1, Folder 34

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Publication Date: 2023-01-12

Description: Handwritten letter, 1 page

Description: Thank you note for reprints

Description: Correspondence

Keywords: People ; Publications

Repository Name: Woods Hole Open Access Server

Language: English

Type: Text

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4

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Using CATS Near-Real-Time Lidar Observations to Monitor and Constrain Volcanic Sulfur Dioxide (SO2) Forecasts (2016)

Da Silva, A. M. ; Hughes, E. J. ; McGill, M. ; [et al.]

In: Other Sources

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Publication Date: 2017-05-11

Description: An eruption of Italian volcano Mount Etna on 3 December 2015 produced fast-moving sulfur dioxide (SO2) and sulfate aerosol clouds that traveled across Asia and the Pacific Ocean, reaching North America in just 5days. The Ozone Profiler and Mapping Suite's Nadir Mapping UV spectrometer aboard the U.S. National Polar-orbiting Partnership satellite observed the horizontal transport of the SO2 cloud. Vertical profiles of the colocated volcanic sulfate aerosols were observed between 11.5 and 13.5 km by the new Cloud Aerosol Transport System (CATS) space-based lidar aboard the International Space Station. Backward trajectory analysis estimates the SO2 cloud altitude at 7-12 km. Eulerian model simulations of the SO2 cloud constrained by CATS measurements produced more accurate dispersion patterns compared to those initialized with the back trajectory height estimate. The near-real-time data processing capabilities of CATS are unique, and this work demonstrates the use of these observations to monitor and model volcanic clouds.

Keywords: Meteorology and Climatology

Type: GSFC-E-DAA-TN41915 , Geophysical Research Letters (ISSN 0094-8276); Volume 43; No. 20; 11,089–11,097

Format: text

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5

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Using Satellite Observations to Evaluate the AeroCOM Volcanic Emissions Inventory and the Dispersal of Volcanic SO2 Clouds in MERRA (2015)

da Silva, Arlindo ; Colarco, Peter ; Krotkov, Nickolay ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: Simulation of volcanic emissions in climate models requires information that describes the eruption of the emissions into the atmosphere. While the total amount of gases and aerosols released from a volcanic eruption can be readily estimated from satellite observations, information about the source parameters, like injection altitude, eruption time and duration, is often not directly known. The AeroCOM volcanic emissions inventory provides estimates of eruption source parameters and has been used to initialize volcanic emissions in reanalysis projects, like MERRA. The AeroCOM volcanic emission inventory provides an eruptions daily SO2 flux and plume top altitude, yet an eruption can be very short lived, lasting only a few hours, and emit clouds at multiple altitudes. Case studies comparing the satellite observed dispersal of volcanic SO2 clouds to simulations in MERRA have shown mixed results. Some cases show good agreement with observations Okmok (2008), while for other eruptions the observed initial SO2 mass is half of that in the simulations, Sierra Negra (2005). In other cases, the initial SO2 amount agrees with the observations but shows very different dispersal rates, Soufriere Hills (2006). In the aviation hazards community, deriving accurate source terms is crucial for monitoring and short-term forecasting (24-h) of volcanic clouds. Back trajectory methods have been developed which use satellite observations and transport models to estimate the injection altitude, eruption time, and eruption duration of observed volcanic clouds. These methods can provide eruption timing estimates on a 2-hour temporal resolution and estimate the altitude and depth of a volcanic cloud. To better understand the differences between MERRA simulations and volcanic SO2 observations, back trajectory methods are used to estimate the source term parameters for a few volcanic eruptions and compared to their corresponding entry in the AeroCOM volcanic emission inventory. The nature of these mixed results is discussed with respect to the source term estimates.

Keywords: Meteorology and Climatology

Type: GSFC-E-DAA-TN20450 , AGU Fall Meeting; Dec 14, 2015 - Dec 18, 2015; San Francisco, CA; United States

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6

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On the Reconstruction of Palaeo-Ice Sheets: Recent Advances and Future Challenges (2015)

Peteet, Dorothy M. ; Fisher, Timothy G. ; Stokes, Chris R. ; [et al.]

In: Other Sources

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Publication Date: 2019-07-13

Description: Reconstructing the growth and decay of palaeo-ice sheets is critical to understanding mechanisms of global climate change and associated sea-level fluctuations in the past, present and future. The significance of palaeo-ice sheets is further underlined by the broad range of disciplines concerned with reconstructing their behaviour, many of which have undergone a rapid expansion since the 1980s. In particular, there has been a major increase in the size and qualitative diversity of empirical data used to reconstruct and date ice sheets, and major improvements in our ability to simulate their dynamics in numerical ice sheet models. These developments have made it increasingly necessary to forge interdisciplinary links between sub-disciplines and to link numerical modelling with observations and dating of proxy records. The aim of this paper is to evaluate recent developments in the methods used to reconstruct ice sheets and outline some key challenges that remain, with an emphasis on how future work might integrate terrestrial and marine evidence together with numerical modelling. Our focus is on pan-ice sheet reconstructions of the last deglaciation, but regional case studies are used to illustrate methodological achievements, challenges and opportunities. Whilst various disciplines have made important progress in our understanding of ice-sheet dynamics, it is clear that data-model integration remains under-used, and that uncertainties remain poorly quantified in both empirically-based and numerical ice-sheet reconstructions. The representation of past climate will continue to be the largest source of uncertainty for numerical modelling. As such, palaeo-observations are critical to constrain and validate modelling. State-of-the-art numerical models will continue to improve both in model resolution and in the breadth of inclusion of relevant processes, thereby enabling more accurate and more direct comparison with the increasing range of palaeo-observations. Thus, the capability is developing to use all relevant palaeo-records to more strongly constrain deglacial (and to a lesser extent pre-LGM) ice sheet evolution. In working towards that goal, the accurate representation of uncertainties is required for both constraint data and model outputs. Close cooperation between modelling and data-gathering communities is essential to ensure this capability is realised and continues to progress.

Keywords: Meteorology and Climatology

Type: GSFC-E-DAA-TN27678 , Quaternary Science Reviews; 125; 15-49

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7

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Freja Studies of the Current-Voltage Relation in Substorm-Related Events (2000)

Erlandsson, R. E. ; Andersson, Laila ; Hughes, T. ; [et al.]

In: Other Sources

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Publication Date: 2019-07-13

Description: Field-aligned currents and electrostatic potentials play important roles in the coupling between the magnetosphere and the ionosphere. If one assumes that the ionosphere-magnetosphere potential difference is mainly due to the mirror force, one can use the single particle adiabatic kinetic theory to describe the system. From this theory, a linear relationship j(sub II) = KV between field-aligned current density j(sub II) and potential drop V along the same field line can be derived, provided that the potential drop is not too large and not too small. With rare exceptions, observational tests of this relation have mainly concentrated on quiet magnetospheric situations, with acceleration voltages V approx. less than 5 kV. Here we use observations from the Freja satellite of precipitating auroral electrons at 1.700 km altitude to study substorm related events, with acceleration voltages up to 20 keV. The observations are found to be consistent with a linear current-voltage relation even i n these conditions, although with values of the field aligned K lower than previously reported (1-5 x 10(exp 11 S/sq m). This can be explained by lower densities and higher characteristic electron energies in the magnetospheric source region of the precipitating electrons. We analyze the data by three different methods, which are all found to be in general agreement. The results are in agreement with a previous study, where the spectra of precipitating electrons --were indirectly inferred by inversion of data from the EISCAT incoherent scatter radar, thereby validating the use of radar data for studies of auroral electrons. Comparisons with previous studies are made, emphasizing the dependence of the results on the type of auroral structure and magnetospheric conditions.

Keywords: Meteorology and Climatology

Type: Paper-2 , Acceleration Processes in Auroral Region (ISSN 0284-1703); IRF-SR-270

Format: text

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8

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Using CATS Near-Real-time Lidar Observations to Monitor and Constrain Volcanic Sulfur Dioxide (SO2) Forecasts (2016)

Hughes, E. J. ; da Silva, A. M. ; Krotkov, N. A. ; [et al.]

In: Other Sources

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Publication Date: 2019-07-13

Description: An eruption of Italian volcano Mount Etna on 3 December 2015 produced fast-moving sulfur dioxide (SO2) and sulfate aerosol clouds that traveled across Asia and the Pacific Ocean, reaching North America in just 5 days. The Ozone Profiler and Mapping Suite's Nadir Mapping UV spectrometer aboard the U.S. National Polar-orbiting Partnership satellite observed the horizontal transport of the SO2 cloud. Vertical profiles of the colocated volcanic sulfate aerosols were observed between 11.5 and 13.5 km by the new Cloud Aerosol Transport System (CATS) space-based lidar aboard the International Space Station. Backward trajectory analysis estimates the SO2 cloud altitude at 7-12 km. Eulerian model simulations of the SO2 cloud constrained by CATS measurements produced more accurate dispersion patterns compared to those initialized with the back trajectory height estimate. The near-real-time data processing capabilities of CATS are unique, and this work demonstrates the use of these observations to monitor and model volcanic clouds.

Keywords: Meteorology and Climatology

Type: GSFC-E-DAA-TN41915 , GSFC-E-DAA-TN40308 , Geophysical Research Letters (ISSN 0094-8276); 43; 20; 11,089–11,097

Format: text

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