Your search keyword '"Mihaly Horanyi"' showing total 3 results

1. New Horizons Observations of the Cosmic Optical Background

Author

Lauer, Tod R., Postman, Marc, Weaver, Harold A., Spencer, John R., Stern, S. Alan, Buie, Marc W., Durda, Daniel D., Lisse, Carey M., Poppe, A. R., Binzel, Richard P., Britt, Daniel T., Buratti, Bonnie J., Cheng, Andrew F., Grundy, W. M., Kavelaars, Mihaly Horanyi J. J., Linscott, Ivan R., McKinnon, William B., Moore, Jeffrey M., Nuñez, J. I., Olkin, Catherine B., Parker, Joel W., Porter, Simon B., Reuter, Dennis C., Robbins, Stuart J., Schenk, Paul, Showalter, Mark R., Singer, Kelsi N., Verbiscer, Anne. J., Young, Leslie A., Lauer, Tod R., Postman, Marc, Weaver, Harold A., Spencer, John R., Stern, S. Alan, Buie, Marc W., Durda, Daniel D., Lisse, Carey M., Poppe, A. R., Binzel, Richard P., Britt, Daniel T., Buratti, Bonnie J., Cheng, Andrew F., Grundy, W. M., Kavelaars, Mihaly Horanyi J. J., Linscott, Ivan R., McKinnon, William B., Moore, Jeffrey M., Nuñez, J. I., Olkin, Catherine B., Parker, Joel W., Porter, Simon B., Reuter, Dennis C., Robbins, Stuart J., Schenk, Paul, Showalter, Mark R., Singer, Kelsi N., Verbiscer, Anne. J., and Young, Leslie A.

Abstract

We used existing data from the New Horizons LORRI camera to measure the optical-band ($0.4\lesssim\lambda\lesssim0.9{\rm\mu m}$) sky brightness within seven high galactic latitude fields. The average raw level measured while New Horizons was 42 to 45 AU from the Sun is $33.2\pm0.5{\rm ~nW ~m^{-2} ~sr^{-1}}.$ This is $\sim10\times$ darker than the darkest sky accessible to the {\it Hubble Space Telescope}, highlighting the utility of New Horizons for detecting the cosmic optical background (COB). Isolating the COB contribution to the raw total requires subtracting scattered light from bright stars and galaxies, faint stars below the photometric detection-limit within the fields, and diffuse Milky Way light scattered by infrared cirrus. We remove newly identified residual zodiacal light from the IRIS $100\mu$m all sky maps to generate two different estimates for the diffuse galactic light (DGL). Using these yields a highly significant detection of the COB in the range ${\rm 15.9\pm 4.2\ (1.8~stat., 3.7~sys.) ~nW ~m^{-2} ~sr^{-1}}$ to ${\rm 18.7\pm 3.8\ (1.8~stat., 3.3 ~sys.)~ nW ~m^{-2} ~sr^{-1}}$ at the LORRI pivot wavelength of 0.608 $\mu$m. Subtraction of the integrated light of galaxies (IGL) fainter than the photometric detection-limit from the total COB level leaves a diffuse flux component of unknown origin in the range ${\rm 8.8\pm4.9\ (1.8 ~stat., 4.5 ~sys.) ~nW ~m^{-2} ~sr^{-1}}$ to ${\rm 11.9\pm4.6\ (1.8 ~stat., 4.2 ~sys.) ~nW ~m^{-2} ~sr^{-1}}$. Explaining it with undetected galaxies requires the galaxy-count faint-end slope to steepen markedly at $V>24$ or that existing surveys are missing half the galaxies with $V< 30.$, Comment: 32 pages, 20 figures. Accepted for publication in ApJ

Published

2020

2. SELMA mission : How do airless bodies interact with space environment? The Moon as an accessible laboratory

Author

Futaana, Yoshifumi, Barabash, Stas, Wieser, Martin, Wurz, Peter, Hurley, Dana, Horanyi, Mihaly, Mall, Urs, Andre, Nicolas, Ivchenko, Nickolay, Oberst, Juergen, Retherford, Kurt, Coates, Andrew, Masters, Adam, Wahlund, Jan-Erik, Kallio, Esa, Futaana, Yoshifumi, Barabash, Stas, Wieser, Martin, Wurz, Peter, Hurley, Dana, Horanyi, Mihaly, Mall, Urs, Andre, Nicolas, Ivchenko, Nickolay, Oberst, Juergen, Retherford, Kurt, Coates, Andrew, Masters, Adam, Wahlund, Jan-Erik, and Kallio, Esa

Abstract

The Moon is an archetypal atmosphere-less celestial body in the Solar System. For such bodies, the environments are characterized by complex interaction among the space plasma, tenuous neutral gas, dust and the outermost layer of the surface. Here we propose the SELMA mission (Surface, Environment, and Lunar Magnetic Anomalies) to study how airless bodies interact with space environment. SELMA uses a unique combination of remote sensing via ultraviolet and infrared wavelengths, and energetic neutral atom imaging, as well as in situ measurements of exospheric gas, plasma, and dust at the Moon. After observations in a lunar orbit for one year, SELMA will conduct an impact experiment to investigate volatile content in the soil of the permanently shadowed area of the Shackleton crater. SELMA also carries an impact probe to sound the Reiner-Gamma mini-magnetosphere and its interaction with the lunar regolith from the SELMA orbit down to the surface. SELMA was proposed to the European Space Agency as a medium-class mission (M5) in October 2016. Research on the SELMA scientific themes is of importance for fundamental planetary sciences and for our general understanding of how the Solar System works. In addition, SELMA outcomes will contribute to future lunar explorations through qualitative characterization of the lunar environment and, in particular, investigation of the presence of water in the lunar soil, as a valuable resource to harvest from the lunar regolith., Part of special issue: Dust, Atmosphere, and Plasma Environment of the Moon and Small Bodies. Edited by Mihaly Horanyi, Alan Stern

Published

2018

3. The Lunar Atmosphere and Dust Environment Explorer Mission (LADEE) / edited by Richard C. Elphic, Christopher T. Russell.

Author

Elphic, Richard C. editor., Russell, Christopher T. editor., SpringerLink (Online service), Elphic, Richard C. editor., Russell, Christopher T. editor., and SpringerLink (Online service)

Abstract

This volume contains five articles describing the mission and its instruments. The first paper, by the project scientist Richard C. Elphic and his colleagues, describes the mission objectives, the launch vehicle, spacecraft and the mission itself. This is followed by a description of LADEE’s Neutral Mass Spectrometer by Paul Mahaffy and company. This paper describes the investigation that directly targets the lunar exosphere, which can also be explored optically in the ultraviolet. In the following article Anthony Colaprete describes LADEE’s Ultraviolet and Visible Spectrometer that operated from 230 nm to 810 nm scanning the atmosphere just above the surface. Not only is there atmosphere but there is also dust that putatively can be levitated above the surface, possibly by electric fields on the Moon’s surface. Mihaly Horanyi leads this investigation, called the Lunar Dust Experiment, aimed at understanding the purported observations of levitated dust. This experiment was also very successful, but in this case their discovery was not the electrostatic levitation of dust, but that the dust was raised by meteoroid impacts. This is not what had been expected but clearly is the explanation that best fits the data. Originally published in Space Science Reviews, Volume 185, Issue 1-4, 2014.

Published

2015