1,912 research outputs found
Anchoring historical sequences using a new source of astro-chronological tie-points
The discovery of past spikes in atmospheric radiocarbon activity, caused by
major solar energetic particle events, has opened up new possibilities for
high-precision chronometry. The two spikes, or Miyake Events, have now been
widely identified in tree-rings that grew in the years 775 and 994 CE.
Furthermore, all other plant material that grew in these years would also have
incorporated the anomalously high concentrations of radiocarbon. Crucially,
some plant-based artefacts, such as papyrus documents, timber beams and linen
garments, can also be allocated to specific positions within long, currently
unfixed, historical sequences. Thus, Miyake Events represent a new source of
tie-points that could provide the means for anchoring early chronologies to the
absolute timescale. Here, we explore this possibility, outlining the most
expeditious approaches, the current challenges and obstacles, and how they
might best be overcome.Comment: 11 pages, accepted to Royal Society Proc
Stellar Systems at Low Radio Frequencies:The Discovery of Radio Exoplanets
For more than thirty years, radio astronomers have searched for auroral emission from exoplanets. With LOFAR we have recently detected strong, highly circularly polarised low-frequency (144 MHz) radio emission associated with a M-dwarf — the expected signpost of such radiation. The star itself is quiescent, with a 130-day rotation period and low X-ray luminosity. In this talk, I will detail how the radio properties of the detection imply that such emission is generated by the presence of an exoplanet in a short period orbit around the star, and our follow-up radial-velocity (RV) observations with Harps-N to confirm the exoplanet's presence. Our study highlights the powerful new and developing synergy between low-frequency radio astronomy and RV observations, with radio emission providing a strong prior on the presence of a short-period planet. I will conclude the talk detailing how the radio detection of an star-exoplanet interaction provides unique information for exoplanet climate and habitability studies, and the extension of our survey to other stellar systems. <p/
Stellar Systems at Low Radio Frequencies:The Discovery of Radio Exoplanets
For more than thirty years, radio astronomers have searched for auroral emission from exoplanets. With LOFAR we have recently detected strong, highly circularly polarised low-frequency (144 MHz) radio emission associated with a M-dwarf — the expected signpost of such radiation. The star itself is quiescent, with a 130-day rotation period and low X-ray luminosity. In this talk, I will detail how the radio properties of the detection imply that such emission is generated by the presence of an exoplanet in a short period orbit around the star, and our follow-up radial-velocity (RV) observations with Harps-N to confirm the exoplanet's presence. Our study highlights the powerful new and developing synergy between low-frequency radio astronomy and RV observations, with radio emission providing a strong prior on the presence of a short-period planet. I will conclude the talk detailing how the radio detection of an star-exoplanet interaction provides unique information for exoplanet climate and habitability studies, and the extension of our survey to other stellar systems
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Solar Energetic-Particle Ground-Level Enhancements and the Solar Cycle
Severe geomagnetic storms appear to be ordered by the solar cycle in a number of ways. They occur more frequently close to solar maximum and the declining phase, are more common in larger solar cycles, and show different patterns of occurrence in odd- and even-numbered solar cycles. Our knowledge of the most extreme space-weather events, however, comes from spikes in cosmogenic-isotope (C-14, Be-10, and Cl-36) records that are attributed to significantly larger solar energetic-particle (SEP) events than have been observed during the space age. Despite both storms and SEPs being driven by solar-eruptive phenomena, the event-by-event correspondence between extreme storms and extreme SEPs is low. Thus, it should not be assumed a priori that the solar-cycle patterns found for storms also hold for SEPs and the cosmogenic-isotope events. In this study, we investigate the solar-cycle trends in the timing and magnitude of the 67 SEP ground-level enhancements (GLEs) recorded by neutron monitors since the mid-1950s. Using a number of models of GLE-occurrence probability, we show that GLEs are around a factor of four more likely around solar maximum than around solar minimum, and that they preferentially occur earlier in even-numbered solar cycles than in odd-numbered cycles. There are insufficient data to conclusively determine whether larger solar cycles produce more GLEs. Implications for putative space-weather events in the cosmogenic-isotope records are discussed. We find that GLEs tend to cluster within a few tens of days, likely due to particularly productive individual active regions, and with approximately 11-year separations, owing to the solar-cycle ordering. However, these timescales would not explain any cosmogenic-isotope spikes requiring multiple extreme SEP events over consecutive years.Peer reviewe
Forward modeling the orbits of companions to pulsating stars from their light travel time variations
Mutual gravitation between a pulsating star and an orbital companion leads to
a time-dependent variation in path length for starlight traveling to Earth.
These variations can be used for coherently pulsating stars, such as the
{\delta} Scuti variables, to constrain the masses and orbits of their
companions. Observing these variations for {\delta} Scuti stars has previously
relied on subdividing the light curve and measuring the average pulsation phase
in equally sized subdivisions, which leads to under-sampling near periapsis. We
introduce a new approach that simultaneously forward-models each sample in the
light curve and show that this method improves upon current sensitivity limits
- especially in the case of highly eccentric and short-period binaries. We find
that this approach is sensitive enough to observe Jupiter mass planets around
{\delta} Scuti stars under ideal conditions, and use gravity-mode pulsations in
the subdwarf B star KIC 7668647 to detect its companion without radial velocity
data. We further provide robust detection limits as a function of the SNR of
the pulsation mode and determine that the minimum detectable light travel time
amplitude for a typical Kepler {\delta} Scuti is around 2 s. This new method
significantly enhances the application of light travel time variations to
detecting short period binaries with pulsating components, and pulsating A-type
exoplanet host stars, especially as a tool for eliminating false positives.Comment: 14 pages, accepted for publication in A
No Massive Companion to the Coherent Radio-Emitting M Dwarf GJ 1151
The recent detection of circularly polarized, long-duration (>8 hr)
low-frequency (~150 MHz) radio emission from the M4.5 dwarf GJ 1151 has been
interpreted as arising from a star-planet interaction via the electron
cyclotron maser instability. The existence or parameters of the proposed
planets have not been determined. Using 20 new HARPS-N observations, we put
99th-percentile upper limits on the mass of any close companion to GJ 1151 at
Msini < 5.6 M earth. With no stellar, brown dwarf, or giant planet companion
likely in a close orbit, our data are consistent with detected radio emission
emerging from a magnetic interaction between a short-period terrestrial-mass
planet and GJ 1151
- …