Your search keyword '"Trevor Leonard"' showing total 21 results

1. Properties and Acceleration Mechanisms of Electrons Up To 200 keV Associated With a Flux Rope Pair and Reconnection X‐Lines Around It in Earth's Plasma Sheet

Author

Weijie Sun, Drew L. Turner, Qile Zhang, Shan Wang, Jan Egedal, Trevor Leonard, James A. Slavin, Qiang Hu, Ian J. Cohen, Kevin Genestreti, Gangkai Poh, Daniel J. Gershman, Andrew Smith, Guan Le, Rumi Nakamura, Barbara L. Giles, Robert E. Ergun, and James L. Burch

Published

2022

2. Characterization of wave-particle interactions in the flux pile-up region of asymmetric reconnection

Author

Matthew Argall, Kristoff Paulson, Narges Ahmadi, Hiroshi Matsui, Trevor Leonard, Drew Turner, Roy Torbert, Olivier Le Contel, Christopher Russell, Werner Magnes, Robert Strangeway, Barbara Giles, Per-Arne Lindqvist, Yuri Khotyaintsev, and Robert Ergun

Published

2019

3. Revisiting the ISN Flow Parameters, using a variable IBEX pointing strategy

Author

David J. McComas, M. A. Lee, Peter Wurz, D. Heirtzler, M. A. Kubiak, Harald Kucharek, Maciej Bzowski, Trevor Leonard, Eberhard Möbius, Nathan A. Schwadron, and S. A. Fuselier

Subjects

Physics, 530 Physics, Plane (geometry), Ecliptic, Astronomy and Astrophysics, Astrophysics, Orbital mechanics, Latitude, Flow (mathematics), Space and Planetary Science, Orientation (geometry), Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, Longitude, Heliosphere

Abstract

The Interstellar Boundary Explorer (IBEX) has observed the interstellar neutral (ISN) gas flow over the past 6 yr during winter/spring when the Earth's motion opposes the ISN flow. Since IBEX observes the interstellar atom trajectories near their perihelion we can use an analytical model based upon orbital mechanics to determine the interstellar parameters. Interstellar flow latitude velocity and temperature are coupled to the flow longitude and are restricted by the IBEX observations to a narrow tube in this parameter space. In our original analysis we found that pointing the spacecraft spin axis slightly out of the ecliptic plane significantly influences the ISN flow vector determination. Introducing the spacecraft spin axis tilt into the analytical model has shown that IBEX observations with various spin axis tilt orientations can substantially reduce the range of acceptable solutions to the ISN flow parameters as a function of flow longitude. The IBEX operations team pointed the IBEX spin axis almost exactly within the ecliptic plane during the 2012 2014 seasons and about 5 degrees below the ecliptic for half of the 2014 season. In its current implementation the analytical model describes the ISN flow most precisely for the spin axis orientation exactly in the ecliptic. This analysis refines the derived ISN flow parameters with a possible reconciliation between velocity vectors found with IBEX and Ulysses resulting in a flow longitude lambda(infinity) = 74 degrees. 5 +/ 1 degrees. 7 and latitude beta(infinity) = 5 degrees.2 +/ 0.degrees 3 but at a substantially higher ISN temperature than previously reported.

Published

2015

4. Interstellar Gas Flow Parameters Derived from Interstellar Boundary Explorer-Lo Observations in 2009 and 2010: Analytical Analysis

Author

Roland Vanderspek, Geoffrey B. Crew, X. Wu, M. A. Kubiak, Stephen A. Fuselier, Trevor Leonard, David J. McComas, Peter Wurz, D. Valovcin, Maciej Bzowski, M. A. Lee, D. Heirtzler, L. Saul, Harald Kucharek, Peter Bochsler, Nathan A. Schwadron, L. Petersen, and Eberhard Möbius

Subjects

Physics, Energetic neutral atom, 010308 nuclear & particles physics, chemistry.chemical_element, Astronomy and Astrophysics, Astrophysics, Inflow, 01 natural sciences, Latitude, Interstellar medium, chemistry, 13. Climate action, Space and Planetary Science, 0103 physical sciences, Longitude, 010303 astronomy & astrophysics, Heliosphere, Helium, Main sequence

Abstract

Neutral atom imaging of the interstellar gas flow in the inner heliosphere provides the most detailed information on physical conditions of the surrounding interstellar medium (ISM) and its interaction with the heliosphere. The Interstellar Boundary Explorer (IBEX) measured neutral H He O and Ne for three years. We compare the He and combined O+Ne flow distributions for two interstellar flow passages in 2009 and 2010 with an analytical calculation which is simplified because the IBEX orientation provides observations at almost exactly the perihelion of the gas trajectories. This method allows separate determination of the key ISM parameters: inflow speed longitude and latitude as well as temperature. A combined optimization as in complementary approaches is thus not necessary. Based on the observed peak position and width in longitude and latitude inflow speed latitude and temperature are found as a function of inflow longitude. The latter is then constrained by the variation of the observed flow latitude as a function of observer longitude and by the ratio of the widths of the distribution in longitude and latitude. Identical results are found for 2009 and 2010: an He flow vector somewhat outside previous determinations (lambda(ISM infinity) = 79 degrees. 0+ 3 degrees.0( 3 degrees. 5) beta(ISM infinity) = 4 degrees.9 +/ 0 degrees.2 V ISM infinity = 23.5 + 3.0( 2.0) km s( 1) T He = 5000 8200 K) suggesting a larger inflow longitude and lower speed. The O+Ne temperature range TO+Ne = 5300 9000 K is found to be close to the upper range for He and consistent with an isothermal medium for all species within current uncertainties.

Published

2012

5. Intensity and Magnetic Field Distribution of Sunspots

Author

Debi Prasad Choudhary and Trevor Leonard

Subjects

Physics, Sunspot, Brightness, Solar observatory, Space and Planetary Science, Observatory, Stellar magnetic field, Starspot, Wilson effect, Astronomy, Astronomy and Astrophysics, Astrophysics, Magnetic field

Abstract

We study the relationship between the brightness (I) and magnetic field (B) distributions of sunspots using 272 samples observed at the San Fernando Observatory and the National Solar Observatory, Kitt Peak, whose characteristics varied widely. We find that the I – B relationship has a quadratic form for the spots with magnetic field less than about 2000 G. The slope of the linear part of the I – B curve varies by about a factor of three for different types of spots. In general the slope increases as the spot approaches disk center. The I – B slope does not have a clear dependency on the spot size but the lower limit appears to increase as a function of the ratio of umbra and penumbra area. The I – B slope changes as a function of age of the sunspots. We discuss various sunspot models using these results.

Published

2008

6. Interstellar Neutral Helium in the Heliosphere from IBEX Observations. I. Uncertainties and Backgrounds in the Data and Parameter Determination Method

Author

Nathan A. Schwadron, Eberhard Möbius, Paweł Swaczyna, M. A. Kubiak, D. Heirtzler, David J. McComas, Harald Kucharek, S. A. Fuselier, Justyna M. Sokół, Trevor Leonard, and Maciej Bzowski

Subjects

Physics, chemistry.chemical_element, Boundary (topology), FOS: Physical sciences, Astronomy and Astrophysics, Expected value, Poisson distribution, Computational physics, symbols.namesake, Data point, chemistry, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Position (vector), symbols, Heliosphere, Helium, Solar and Stellar Astrophysics (astro-ph.SR), Spin-½

Abstract

This paper is one of three companion papers presenting the results of our in-depth analysis of the interstellar neutral helium (ISN He) observations carried out using the IBEX-Lo during the first six Interstellar Boundary Explorer (IBEX) observation seasons. We derive corrections for losses due to the limited throughput of the interface buffer and determine the IBEX spin-axis pointing. We develop an uncertainty system for the data, taking into account the resulting correlations between the data points. This system includes uncertainties due to Poisson statistics, background, spin-axis determination, systematic deviation of the boresight from the prescribed position, correction for the interface buffer losses, and the expected Warm Breeze (WB) signal. Subsequently, we analyze the data from 2009 to examine the role of various components of the uncertainty system. We show that the ISN He flow parameters are in good agreement with the values obtained by the original analysis. We identify the WB as the principal contributor to the global $\chi^2$ values in previous analyses. Other uncertainties have a much milder role and their contributions are comparable to each other. The application of this uncertainty system reduced the minimum $\chi^2$ value 4-fold. The obtained $\chi^2$ value, still exceeding the expected value, suggests that either the uncertainty system may still be incomplete or the adopted physical model lacks a potentially important element, which is likely an imperfect determination of the WB parameters. The derived corrections and uncertainty system are used in the accompanying paper by Bzowski et al. in an analysis of the data from six seasons., Comment: 43 pages, 9 figures

Published

2015

7. Interstellar Gas Flow Vector and Temperature Determination over 5 Years of IBEX Observations

Author

Peter Wurz, D. Heirtzler, M. A. Lee, S. A. Fuselier, Justyna M. Sokół, M. A. Kubiak, David J. McComas, Harald Kucharek, Maciej Bzowski, Trevor Leonard, Nathan A. Schwadron, and Eberhard Möbius

Subjects

Physics, Local Interstellar Cloud, History, Solar System, 530 Physics, Astronomy, Inflow, Computer Science Applications, Education, Pickup Ion, Flow (mathematics), Orbital motion, Physics::Space Physics, Longitude, Heliosphere, Astrophysics::Galaxy Astrophysics

Abstract

The Interstellar Boundary Explorer (IBEX) observes the interstellar neutral gas flow trajectories at their perihelion in Earth's orbit every year from December through early April, when the Earth's orbital motion is into the oncoming flow. These observations have defined a narrow region of possible, but very tightly coupled interstellar neutral flow parameters, with inflow speed, latitude, and temperature as well-defined functions of inflow longitude. The best- fit flow vector is different by ≈ 3° and lower by ≈ 3 km/s than obtained previously with Ulysses GAS, but the temperature is comparable. The possible coupled parameter space reaches to the previous flow vector, but only for a substantially higher temperature (by ≈ 2000 K). Along with recent pickup ion observations and including historical observations of the interstellar gas, these findings have led to a discussion, whether the interstellar gas flow into the solar system has been stable or variable over time. These intriguing possibilities call for more detailed analysis and a longer database. IBEX has accumulated observations over six interstellar flow seasons. We review key observations and refinements in the analysis, in particular, towards narrowing the uncertainties in the temperature determination. We also address ongoing attempts to optimize the flow vector determination through varying the IBEX spacecraft pointing and discuss related implications for the local interstellar cloud and its interaction with the heliosphere.

Published

2015

8. Correcting the record on the analysis of IBEX and STEREO data regarding variations in the neutral interstellar wind

Author

Eberhard Möbius, Nathan A. Schwadron, Dave McComas, Trevor Leonard, P. C. Frisch, Justyna M. Sokół, Maciej Bzowski, George Livadiotis, and Christian Drews

Subjects

Physics, Solar System, Astrophysics::High Energy Astrophysical Phenomena, Interstellar cloud, Ecliptic, Astronomy, FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics - Astrophysics of Galaxies, Interstellar medium, Pickup Ion, Solar wind, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Astrophysics of Galaxies (astro-ph.GA), Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Longitude, Heliosphere, Astrophysics::Galaxy Astrophysics, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

The journey of the Sun through space carries the solar system through a dynamic interstellar environment that is presently characterized by Mach 1 motion between the heliosphere and the surrounding interstellar medium (ISM). The interaction between the heliosphere and ISM is an evolving process due to the variable solar wind and to interstellar turbulence. Frisch et al. presented a meta-analysis of the historical data on the interstellar wind flowing through the heliosphere and concluded that temporal changes in the ecliptic longitude of the wind were statistically indicated by the data available in the refereed literature at the time of that writing. Lallement and Bertaux disagree with this result, and suggested, for instance, that a key instrumental response function of IBEX-Lo was incorrect and that the STEREO pickup ion data are unsuitable for diagnosing the flow of interstellar neutrals through the heliosphere. Here we show that temporal variations in the interstellar wind through the heliosphere are consistent with our knowledge of local ISM. The statistical analysis of the historical helium wind data is revisited, and a recent correction of a typographical error in the literature is incorporated into the new fits. With this correction, and including no newer IBEX results, these combined data still indicate that a change in the longitude of the interstellar neutral wind over the past forty years is statistically likely, but that a constant flow longitude is now also statistically possible. It is shown that the IBEX instrumental response function is known, and that the STEREO pickup ion data have been correctly utilized in this analysis., Comment: Astrophysical Journal, in press

Published

2015

9. Direct Observations of Interstellar H, He, and O by the Interstellar Boundary Explorer

Author

Peter Wurz, L. Petersen, Stephen A. Fuselier, D. Heirtzler, David J. McComas, J. A. Scheer, M. A. Lee, Maciej Bzowski, Manfred Witte, Trevor Leonard, Vlad Izmodenov, L. Saul, Harald Kucharek, Peter Bochsler, Herbert O. Funsten, Eberhard Möbius, Nathan A. Schwadron, Geoffrey B. Crew, A. G. Ghielmetti, and M. A. Kubiak

Subjects

Physics, Solar System, Multidisciplinary, Energetic neutral atom, Ecliptic, Astronomy, chemistry.chemical_element, Astrophysics, Interstellar medium, Gravitation, chemistry, Radiation pressure, Ionization, Helium

Abstract

What's Happening in the Heliosphere The influence of the Sun is felt well beyond the orbits of the planets. The solar wind is a stream of charged particles emanating from the Sun that carves a bubble in interstellar space known as the heliosphere and shrouds the entire solar system. The edge of the heliosphere, the region where the solar wind interacts with interstellar space, is largely unexplored. Voyager 1 and 2 crossed this boundary in 2004 and 2007, respectively, providing detailed but only localized information. In this issue (see the cover), McComas et al. (p. 959 , published online 15 October), Fuselier et al. (p. 962 , published online 15 October), Funsten et al. (p. 964 , published online 15 October), and Möbius et al. (p. 969 , published online 15 October) present data taken by NASA's Interstellar Boundary Explorer (IBEX). Since early 2009, IBEX has been building all-sky maps of the emissions of energetic neutral atoms produced at the boundary between the heliosphere and the interstellar medium. These maps have unexpectedly revealed a narrow band of emission that bisects the two Voyager locations at energies ranging from 0.2 to 6 kiloelectron volts. Emissions from the band are two- to threefold brighter than outside the band, in contrast to current models that predict much smaller variations across the sky. By comparing the IBEX observations with models of the heliosphere, Schwadron et al. (p. 966 , published online 15 October) show that to date no model fully explains the observations. The model they have developed suggests that the interstellar magnetic field plays a stronger role than previously thought. In addition to the all-sky maps, IBEX measured the signatures of H, He, and O flowing into the heliosphere from the interstellar medium. In a related report, Krimigis et al. (p. 971 , published online 15 October) present an all-sky image of energetic neutral atoms with energies ranging between 6 and 13 kiloelectron volts obtained with the Ion and Neutral Camera onboard the Cassini spacecraft orbiting Saturn. It shows that parts of the structure observed by IBEX extend to high energies. These data indicate that the shape of the heliosphere is not consistent with that of a comet aligned in the direction of the Sun's travel through the galaxy as was previously thought.

Published

2009

10. THE ANALYTICAL STRUCTURE OF THE PRIMARY INTERSTELLAR HELIUM DISTRIBUTION FUNCTION IN THE HELIOSPHERE

Author

Martin A. Lee, Trevor Leonard, and Eberhard Möbius

Subjects

Local Interstellar Cloud, Physics, Hyperbolic trajectory, Solid angle, Ecliptic, chemistry.chemical_element, Astronomy and Astrophysics, Astrophysics, Distribution function, chemistry, Thermal velocity, Space and Planetary Science, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, Helium, Heliosphere

Abstract

A new analytical model based on the previous work of Lee et al. is presented for the distribution of interstellar helium in the heliosphere. The model is tailored for comparison with the IBEX-Lo observations in order to determine the bulk velocity and temperature of helium in the local interstellar cloud. The model includes solar gravity, spherically symmetric stationary ionization rates, transformation to the Earth/IBEX frame of reference, the IBEX viewing geometry with small spin-axis tilt, and integration of the atom differential intensity over energy and the instrument collimator solid angle. The analysis employs an expansion of the count rate about the peak of the velocity distribution to second order in the magnitudes of several small quantities: the ratio of the helium thermal speed to its bulk speed, the angle between the bulk velocity and the ecliptic, the two angles describing the tilt of the IBEX spin-axis away from Sun-pointing, the collimator angular width, and the angular difference between the observing longitude and the longitude where the projection of the bulk velocity onto the ecliptic is tangential to Earth's orbit. The model reveals the evolving ellipsoidal shape of the helium distribution as it moves along its average hyperbolic orbit. For specified interstellar parameters, the model predicts the latitudinal and longitudinal structure of the helium distribution. The model is in reasonable agreement with IBEX observations and the predictions of the other available models.

Published

2015

11. DETERMINATION OF INTERSTELLAR He PARAMETERS USING FIVE YEARS OF DATA FROM THE IBEX : BEYOND CLOSED FORM APPROXIMATIONS

Author

D. Heirtzler, Paweł Swaczyna, Nathan A. Schwadron, Trevor Leonard, Eberhard Möbius, F. Rahmanifard, M. A. Kubiak, Dave McComas, P. C. Frisch, Justyna M. Sokół, Stephen A. Fuselier, Maciej Bzowski, and Harald Kucharek

Subjects

Physics, Closed form approximation, Space and Planetary Science, Astronomy, Astronomy and Astrophysics, Astrophysics

Published

2015

12. INTERSTELLAR NEUTRAL HELIUM IN THE HELIOSPHERE FROM IBEX OBSERVATIONS. III. MACH NUMBER OF THE FLOW, VELOCITY VECTOR, AND TEMPERATURE FROM THE FIRST SIX YEARS OF MEASUREMENTS

Author

S. A. Fuselier, Eberhard Möbius, Maciej Bzowski, D. Heirtzler, Nathan A. Schwadron, Trevor Leonard, Harald Kucharek, André Galli, Peter Wurz, M. A. Kubiak, David J. McComas, Justyna M. Sokół, and Paweł Swaczyna

Subjects

Physics, FOS: Physical sciences, chemistry.chemical_element, Astronomy and Astrophysics, Computational physics, symbols.namesake, Astrophysics - Solar and Stellar Astrophysics, Flow velocity, chemistry, Mach number, Space and Planetary Science, symbols, Solar and Stellar Astrophysics (astro-ph.SR), Helium, Heliosphere

Abstract

We analyzed observations of interstellar neutral helium (ISN~He) obtained from the Interstellar Boundary Explorer (IBEX) satellite during its first six years of operation. We used a refined version of the ISN~He simulation model, presented in the companion paper by Sokol_et al. 2015, and a sophisticated data correlation and uncertainty system and parameter fitting method, described in the companion paper by Swaczyna et al 2015. We analyzed the entire data set together and the yearly subsets, and found the temperature and velocity vector of ISN~He in front of the heliosphere. As seen in the previous studies, the allowable parameters are highly correlated and form a four-dimensional tube in the parameter space. The inflow longitudes obtained from the yearly data subsets show a spread of ~6 degree, with the other parameters varying accordingly along the parameter tube, and the minimum chi-square value is larger than expected. We found, however, that the Mach number of the ISN~He flow shows very little scatter and is thus very tightly constrained. It is in excellent agreement with the original analysis of ISN~He observations from IBEX and recent reanalyses of observations from Ulysses. We identify a possible inaccuracy in the Warm Breeze parameters as the likely cause of the scatter in the ISN~He parameters obtained from the yearly subsets, and we suppose that another component may exist in the signal, or a process that is not accounted for in the current physical model of ISN~He in front of the heliosphere. From our analysis, the inflow velocity vector, temperature, and Mach number of the flow are equal to lambda_ISNHe = 255.8 +/- 0.5 degree, beta_ISNHe = 5.16 +/- 0.10 degree, T_ISNHe = 7440 +/- 260 K, v_ISNHe = 25.8 +/- 0.4$ km/s, and M_ISNHe = 5.079 +/- 0.028, with uncertainties strongly correlated along the parameter tube., Comment: Updated references

Published

2015

13. LOCAL INTERSTELLAR MEDIUM: SIX YEARS OF DIRECT SAMPLING BY IBEX

Author

Paweł Swaczyna, André Galli, S. A. Fuselier, Trevor Leonard, M. A. Lee, J. Park, P. C. Frisch, M. A. Kubiak, David J. McComas, Justyna M. Sokół, Eberhard Möbius, Peter Wurz, Maciej Bzowski, Nathan A. Schwadron, Vlad Izmodenov, Brian E. Wood, and Olga Katushkina

Subjects

Physics, education.field_of_study, 010504 meteorology & atmospheric sciences, Energetic neutral atom, Population, Ecliptic, Astronomy, Interplanetary medium, Astronomy and Astrophysics, Astrophysics, 01 natural sciences, Interstellar medium, Heliophysics, 13. Climate action, Space and Planetary Science, 0103 physical sciences, education, 010303 astronomy & astrophysics, Interstellar probe, Heliosphere, 0105 earth and related environmental sciences

Abstract

The Interstellar Boundary Explorer (IBEX) has been directly observing neutral atoms from the local interstellar medium for the last six years (2009–2014). This paper ties together the 14 studies in this Astrophysical Journal Supplement Series Special Issue, which collectively describe the IBEX interstellar neutral results from this epoch and provide a number of other relevant theoretical and observational results. Interstellar neutrals interact with each other and with the ionized portion of the interstellar population in the “pristine” interstellar medium ahead of the heliosphere. Then, in the heliosphereʼs close vicinity, the interstellar medium begins to interact with escaping heliospheric neutrals. In this study, we compare the results from two major analysis approaches led by IBEX groups in New Hampshire and Warsaw. We also directly address the question of the distance upstream to the pristine interstellar medium and adjust both sets of results to a common distance of ~1000 AU. The two analysis approaches are quite different, but yield fully consistent measurements of the interstellar He flow properties, further validating our findings. While detailed error bars are given for both approaches, we recommend that for most purposes, the community use “working values” of ~25.4 km s⁻¹, ~75°7 ecliptic inflow longitude, ~−5°1 ecliptic inflow latitude, and ~7500 K temperature at ~1000 AU upstream. Finally, we briefly address future opportunities for even better interstellar neutral observations to be provided by the Interstellar Mapping and Acceleration Probe mission, which was recommended as the next major Heliophysics mission by the NRCʼs 2013 Decadal Survey.

Published

2015

14. INTERSTELLAR FLOW AND TEMPERATURE DETERMINATION WITH IBEX : ROBUSTNESS AND SENSITIVITY TO SYSTEMATIC EFFECTS

Author

Peter Wurz, Maciej Bzowski, David J. McComas, D. Heirtzler, M. A. Kubiak, Harald Kucharek, S. A. Fuselier, P. C. Frisch, Justyna M. Sokół, M. A. Lee, Paweł Swaczyna, Eberhard Möbius, Nathan A. Schwadron, and Trevor Leonard

Subjects

Physics, Meteorology, Spacecraft, business.industry, chemistry.chemical_element, Astronomy and Astrophysics, Parameter space, Geodesy, Latitude, chemistry, Flow (mathematics), Flow velocity, Space and Planetary Science, Physics::Space Physics, business, Longitude, Spin (aerodynamics), Helium

Abstract

The Interstellar Boundary Explorer (IBEX) samples the interstellar neutral (ISN) gas flow of several species every year from December through late March when the Earth moves into the incoming flow. The first quantitative analyses of these data resulted in a narrow tube in four-dimensional interstellar parameter space, which couples speed, flow latitude, flow longitude, and temperature, and center values with approximately 3° larger longitude and 3 km s⁻¹ lower speed, but with temperatures similar to those obtained from observations by the Ulysses spacecraft. IBEX has now recorded six years of ISN flow observations, providing a large database over increasing solar activity and using varying viewing strategies. In this paper, we evaluate systematic effects that are important for the ISN flow vector and temperature determination. We find that all models in use return ISN parameters well within the observational uncertainties and that the derived ISN flow direction is resilient against uncertainties in the ionization rate. We establish observationally an effective IBEX-Lo pointing uncertainty of ±0°18 in spin angle and confirm an uncertainty of ±0°1 in longitude. We also show that the IBEX viewing strategy with different spin-axis orientations minimizes the impact of several systematic uncertainties, and thus improves the robustness of the measurement. The Helium Warm Breeze has likely contributed substantially to the somewhat different center values of the ISN flow vector. By separating the flow vector and temperature determination, we can mitigate these effects on the analysis, which returns an ISN flow vector very close to the Ulysses results, but with a substantially higher temperature. Due to coupling with the ISN flow speed along the ISN parameter tube, we provide the temperature Tvisn∞=8710+440/-680 K for Visn∞=26 km s⁻¹ for comparison, where most of the uncertainty is systematic and likely due to the presence of the Warm Breeze.

Published

2015

15. WARMER LOCAL INTERSTELLAR MEDIUM: A POSSIBLE RESOLUTION OF THEULYSSES-IBEXENIGMA

Author

Harald Kucharek, Eberhard Möbius, Paweł Swaczyna, P. C. Frisch, S. A. Fuselier, M. A. Kubiak, Nathan A. Schwadron, Maciej Bzowski, Justyna M. Sokół, David J. McComas, Manfred Witte, and Trevor Leonard

Subjects

Physics, Interstellar medium, Space and Planetary Science, Resolution (electron density), Ecliptic, Interplanetary medium, Astronomy, Astronomy and Astrophysics, Astrophysics, Parameter space, Longitude, Heliosphere, Latitude

Abstract

Interstellar Boundary Explorer (IBEX) measurements from 2009-2010 identified a set of possible solutions with very tight coupling between the interstellar He inflow longitude, latitude, speed, and temperature. The center of this allowable parameter space suggested that the heliosphere could be moving more slowly and in a slightly different direction with respect to the interstellar medium than indicated by earlier Ulysses observations. In this study we examine data from 2012-2014 and compare results from an analytic analysis and a detailed computer model. For observations where the IBEX spacecraft pointing is near the ecliptic plane, the latest measurements indicate a different portion of IBEX's four-dimensional tube of possible parameters—one that is more consistent with the Ulysses flow direction and speed, but with a much higher temperature. Together, the current combined IBEX/Ulysses values we obtain are V ISM∞ ~ 26 km s–1, λISM∞ ~ 75°, βISM∞ ~ –5°, and T He∞ ~ 7000-9500 K. These indicate that the heliosphere is in a substantially warmer region of the interstellar medium than thought from the earlier Ulysses observations alone, and that this warmer region may be roughly isothermal. However, measurements taken when IBEX was pointing ~5° south of the ecliptic are inconsistent with this solution and suggest a slower speed, lower temperature, and flow direction similar to IBEX's prior central values. IBEX measures much deeper into the tails of the distributions of the inflowing interstellar material than Ulysses did and these observations indicate that the heliosphere's interstellar interaction is likely far more complex and interesting than previously appreciated.

Published

2015

16. THE Ne-TO-O ABUNDANCE RATIO OF THE INTERSTELLAR MEDIUM FROMIBEX-Lo OBSERVATIONS

Author

Harald Kucharek, J. Park, M. A. Kubiak, Trevor Leonard, Dave McComas, S. A. Fuselier, Maciej Bzowski, Eberhard Möbius, and Justyna M. Sokół

Subjects

Local Interstellar Cloud, Physics, Earth's orbit, chemistry.chemical_element, Astronomy and Astrophysics, Astrophysics, Abundance of the chemical elements, Interstellar medium, Neon, chemistry, Space and Planetary Science, Abundance (ecology), Ionization, sense organs, Astrophysics::Earth and Planetary Astrophysics, Astrophysics::Galaxy Astrophysics, Heliosphere

Abstract

In this paper we report on a two-year study to estimate the Ne/O abundance ratio in the gas phase of the local interstellar cloud (LIC). Based on the first two years of observations with the Interstellar Boundary Explorer, we determined the fluxes of interstellar neutral (ISN) O and Ne atoms at the Earth's orbit in spring 2009 and 2010. A temporal variation of the Ne/O abundance ratio at the Earth's orbit could be expected due to solar cycle-related effects such as changes of ionization. However, this study shows that there is no significant change in the Ne/O ratio at the Earths orbit from 2009 to 2010. We used time-dependent survival probabilities of the ISNs to calculate the Ne/O abundance ratio at the termination shock. Then we estimated the Ne/O abundance ratio in the gas phase of the LIC with the use of filtration factors and the ionization fractions. From our analysis, the Ne/O abundance ratio in the LIC is 0.33 ± 0.07, which is in agreement with the abundance ratio inferred from pickup-ion measurements.

Published

2014

17. WARM BREEZE FROM THE STARBOARD BOW: A NEW POPULATION OF NEUTRAL HELIUM IN THE HELIOSPHERE

Author

S. Grzedzielski, S. A. Fuselier, Eberhard Moebius, Dmitry Alexashov, Maciej Bzowski, Paweł Swaczyna, Peter Wurz, Vladislav Izmodenov, David J. McComas, Trevor Leonard, M. A. Kubiak, and Justyna M. Sokół

Subjects

Local Interstellar Cloud, 010504 meteorology & atmospheric sciences, Population, FOS: Physical sciences, chemistry.chemical_element, Inflow, Astrophysics, 7. Clean energy, 01 natural sciences, 0103 physical sciences, education, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), Physics::Atmospheric and Oceanic Physics, Astrophysics::Galaxy Astrophysics, Helium, 0105 earth and related environmental sciences, Physics, education.field_of_study, Earth's orbit, Astronomy and Astrophysics, Plasma, Pickup Ion, Astrophysics - Solar and Stellar Astrophysics, chemistry, 13. Climate action, Space and Planetary Science, Physics::Space Physics, Heliosphere

Abstract

We investigate the signals from neutral He atoms observed from Earth orbit in 2010 by IBEX. The full He signal observed during the 2010 observation season can be explained as a superposition of pristine neutral interstellar He gas and an additional population of neutral He that we call the Warm Breeze. The Warm Breeze is approximately two-fold slower and 2.5 times warmer than the primary interstellar He population, and its density in front of the heliosphere is ~7% that of the neutral interstellar helium. The inflow direction of the Warm Breeze differs by ~19deg from the inflow direction of interstellar gas. The Warm Breeze seems a long-term feature of the heliospheric environment. It has not been detected earlier because it is strongly ionized inside the heliosphere, which brings it below the threshold of detection via pickup ion and heliospheric backscatter glow observations, as well as by the direct sampling of GAS/Ulysses. Possible sources for the Warm Breeze include (1) the secondary population of interstellar helium, created via charge exchange and perhaps elastic scattering of neutral interstellar He atoms on interstellar He+ ions in the outer heliosheath, or (2) a gust of interstellar He originating from a hypothetic wave train in the Local Interstellar Cloud. A secondary population is expected from models, but the characteristics of the Warm Breeze do not fully conform to modeling results. If, nevertheless, this is the explanation, IBEX-Lo observations of the Warm Breeze provide key insights into the physical state of plasma in the outer heliosheath. If the second hypothesis is true, the source is likely to be located within a few thousand of AU from the Sun, which is the propagation range of possible gusts of interstellar neutral helium with the Warm Breeze characteristics against dissipation via elastic scattering in the Local Cloud., submitted to ApJS

Published

2014

18. LOCAL INTERSTELLAR NEUTRAL HYDROGEN SAMPLED IN SITU BY IBEX

Author

Lukas Saul, Diego Rodriguez, Trevor Leonard, Peter Wurz, Nathan A. Schwadron, Dave McComas, Maciej Bzowski, Eberhard Möbius, Geoff Crew, Harald Kucharek, Stephen A. Fuselier, and J. A. Scheer

Subjects

In situ, Physics, Hydrogen, 010308 nuclear & particles physics, FOS: Physical sciences, chemistry.chemical_element, Astronomy and Astrophysics, Astrophysics, 01 natural sciences, Interstellar medium, Astrophysics - Solar and Stellar Astrophysics, chemistry, Radiation pressure, 13. Climate action, Space and Planetary Science, Ionization, Physics::Space Physics, 0103 physical sciences, Physics::Atomic Physics, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), Astrophysics::Galaxy Astrophysics, Heliosphere, Helium, Solar variation

Abstract

Hydrogen gas is the dominant component of the local interstellar medium. However owing to ionization and interaction with the heliosphere direct sampling of neutral hydrogen in the inner heliosphere is more difficult than sampling the local interstellar neutral helium which penetrates deep into the heliosphere. In this paper we report on the first detailed analysis of the direct sampling of neutral hydrogen from the local interstellar medium. We confirm that the arrival direction of hydrogen is offset from that of the local helium component. We further report the discovery of a variation of the penetrating hydrogen over the first two years of Interstellar Boundary Explorer observations. Observations are consistent with hydrogen experiencing an effective ratio of outward solar radiation pressure to inward gravitational force greater than unity (mu > 1); the temporal change observed in the local interstellar hydrogen flux can be explained with solar variability.

Published

2012

19. NEUTRAL INTERSTELLAR HELIUM PARAMETERS BASED ON IBEX-Lo OBSERVATIONS AND TEST PARTICLE CALCULATIONS

Author

Eberhard Möbius, Nathan A. Schwadron, Geoffrey B. Crew, Trevor Leonard, Maciej Bzowski, Justyna M. Sokół, Marzena A. Kubiak, D. Heirtzler, Harald Kucharek, Peter Bochsler, Stephen A. Fuselier, David J. McComas, and M. Hlond

Subjects

Physics, Local Interstellar Cloud, Solar System, education.field_of_study, Energetic neutral atom, Interstellar cloud, Population, chemistry.chemical_element, Astronomy and Astrophysics, Astrophysics, Interstellar medium, chemistry, Space and Planetary Science, Physics::Space Physics, education, Astrophysics::Galaxy Astrophysics, Heliosphere, Helium

Abstract

Because of its high ionization potential and weak interaction with hydrogen, neutral interstellar helium (NISHe) is almost unaffected at the heliospheric interface with the interstellar medium and freely enters the solar system. This second most abundant species provides some of the best information on the characteristics of the interstellar gas in the local interstellar cloud. The Interstellar Boundary Explorer (IBEX) is the second mission to directly detect NISHe. We present a comparison between recent IBEX NISHe observations and simulations carried out using a well-tested quantitative simulation code. Simulation and observation results compare well for times when measured fluxes are dominated by NISHe (and contributions from other species are small). Differences between simulations and observations indicate a previously undetected secondary population of neutral helium, likely produced by interaction of interstellar helium with plasma in the outer heliosheath. Interstellar neutral parameters are statistically different from previous in situ results obtained mostly from the GAS/Ulysses experiment, but they do agree with the local interstellar flow vector obtained from studies of interstellar absorption: the newly established flow direction is ecliptic longitude 792, latitude –51, the velocity is ~22.8 km s–1, and the temperature is 6200 K. These new results imply a markedly lower absolute velocity of the gas and thus significantly lower dynamic pressure on the boundaries of the heliosphere and different orientation of the Hydrogen Deflection Plane compared to prior results from Ulysses. A different orientation of this plane also suggests a new geometry of the interstellar magnetic field, and the lower dynamic pressure calls for a compensation by other components of the pressure balance, most likely a higher density of interstellar plasma and strength of interstellar magnetic field.

Published

2012

20. The Caenorhabditis elegans genome sequencing project: first steps in automation

Author

Roger Lucke, Nicky Smaldon, Trevor Leonard Hawkins, and Andrew J. Watson

Subjects

Genetics, Multidisciplinary, biology, Base Sequence, Shotgun sequencing, business.industry, Computational biology, Robotics, biology.organism_classification, Quantitative Biology::Genomics, Automation, DNA sequencing, Computer Science::Robotics, Robotic systems, Animals, business, Caenorhabditis elegans

Abstract

Novel biochemical processes using magnetic particles have been automated to provide a robotic system to perform processes for large-scale shotgun sequencing.

Published

1993

21. Meeting report: discussions and preliminary findings on extracellular RNA measurement methods from laboratories in the NIH Extracellular RNA Communication Consortium

Author

Louise C. Laurent, Asim B. Abdel-Mageed, P. David Adelson, Jorge Arango, Leonora Balaj, Xandra Breakefield, Elizabeth Carlson, Bob S. Carter, Blanca Majem Cavaller, Clark C. Chen, Emanuele Cocucci, Kirsty Danielson, Amanda Courtright, Saumya Das, Zakaria Y. Abd Elmageed, Daniel Enderle, Alan Ezrin, Marc Ferrer, Jane Freedman, David Galas, Roopali Gandhi, Matthew J. Huentelman, Kendall Van Keuren-Jensen, Yashar Kalani, Yong Kim, Anna M. Krichevsky, Charles Lai, Madhu Lal-Nag, Clara D. Laurent, Trevor Leonardo, Feng Li, Ivana Malenica, Debasis Mondal, Parham Nejad, Tushar Patel, Robert L. Raffai, Renee Rubio, Johan Skog, Robert Spetzler, Jie Sun, Kahraman Tanriverdi, Kasey Vickers, Liang Wang, Yaoyu Wang, Zhiyun Wei, Howard L. Weiner, David Wong, Irene K. Yan, Ashish Yeri, and Stephen Gould

Subjects

extracellular RNA, extracellular vesicles, exosomes, microvesicles, RNA sequencing, Cytology, QH573-671

Abstract

Extracellular RNAs (exRNAs) have been identified in all tested biofluids and have been associated with a variety of extracellular vesicles, ribonucleoprotein complexes and lipoprotein complexes. Much of the interest in exRNAs lies in the fact that they may serve as signalling molecules between cells, their potential to serve as biomarkers for prediction and diagnosis of disease and the possibility that exRNAs or the extracellular particles that carry them might be used for therapeutic purposes. Among the most significant bottlenecks to progress in this field is the lack of robust and standardized methods for collection and processing of biofluids, separation of different types of exRNA-containing particles and isolation and analysis of exRNAs. The Sample and Assay Standards Working Group of the Extracellular RNA Communication Consortium is a group of laboratories funded by the U.S. National Institutes of Health to develop such methods. In our first joint endeavour, we held a series of conference calls and in-person meetings to survey the methods used among our members, placed them in the context of the current literature and used our findings to identify areas in which the identification of robust methodologies would promote rapid advancements in the exRNA field.

Published

2015