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1. Supernova Dust Evolution Probed by Deep-sea ⁶⁰ Fe Time History

   https://doi.org/10.3847/1538-4357/acb699  

   Ertel, Adrienne F.; Fry, Brian J.; Fields, Brian D.; Ellis, John (April 2023, The Astrophysical Journal)

   Abstract There is a wealth of data on live, undecayed⁶⁰Fe (t_1/2= 2.6 Myr) in deep-sea deposits, the lunar regolith, cosmic rays, and Antarctic snow, which is interpreted as originating from the recent explosions of at least two near-Earth supernovae. We use the⁶⁰Fe profiles in deep-sea sediments to estimate the timescale of supernova debris deposition beginning ∼3 Myr ago. The available data admits a variety of different profile functions, but in all cases the best-fit⁶⁰Fe pulse durations are >1.6 Myr when all the data is combined. This timescale far exceeds the ≲0.1 Myr pulse that would be expected if⁶⁰Fe was entrained in the supernova blast wave plasma. We interpret the long signal duration as evidence that⁶⁰Fe arrives in the form of supernova dust, whose dynamics are separate from but coupled to the evolution of the blast plasma. In this framework, the >1.6 Myr is that for dust stopping due to drag forces. This scenario is consistent with the simulations in Fry et al. (2020), where the dust is magnetically trapped in supernova remnants and thereby confined around regions of the remnant dominated by supernova ejects, where magnetic fields are low. This picture fits naturally with models of cosmic-ray injection of refractory elements as sputtered supernova dust grains and implies that the recent⁶⁰Fe detections in cosmic rays complement the fragments of grains that survived to arrive on the Earth and Moon. Finally, we present possible tests for this scenario. 

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2. Distances to Recent Near-Earth Supernovae from Geological and Lunar ⁶⁰ Fe

   https://doi.org/10.3847/1538-4357/ad5a93  

   Ertel, Adrienne_F; Fields, Brian_D (September 2024, The Astrophysical Journal)

   Abstract Near-Earth supernova blasts which engulf the solar system have left traces of their ejecta in the geological and lunar records. There is now a wealth of data on live radioactive⁶⁰Fe pointing to a supernova at 3 Myr ago, as well as the recent discovery of an event at 7 Myr ago. We use the available measurements to evaluate the distances to these events. For the better analyzed supernova at 3 Myr, samples include deep-sea sediments, ferromanganese crusts, and lunar regolith; we explore the consistency among and across these measurements, which depends sensitively on the uptake of iron in the samples as well as possible anisotropies in the⁶⁰Fe fallout. There is also significant uncertainty in the astronomical parameters needed for these calculations. We take the opportunity to perform a parameter study on the effects that the ejected⁶⁰Fe mass from a core-collapse supernova and the fraction of dust that survives the remnant have on the resulting distance. We find that with an ejected⁶⁰Fe mass of 3 × 10⁻⁵M_⊙and a dust fraction of 10%, the distance range for the supernova 3 Myr ago isD∼ 20–140 pc, with the most likely range between 50 and 65 pc. Using the same astrophysical parameters, the distance for the supernova at 7 Myr ago isD∼ 110 pc. We close with a brief discussion of geological and astronomical measurements that can improve these results. 

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3. Heliospheric Compression Due to Recent Nearby Supernova Explosions

   https://doi.org/10.3847/1538-4357/ac77f1  

   Miller, Jesse A.; Fields, Brian D. (July 2022, The Astrophysical Journal)

   Abstract The widespread detection of 60 Fe in geological and lunar archives provides compelling evidence for recent nearby supernova explosions within ∼100 pc at 3 and 7 Myr ago. The blasts from these explosions had a profound effect on the heliosphere. We perform new calculations to study the compression of the heliosphere due to a supernova blast. Assuming a steady but non-isotropic solar wind, we explore a range of properties appropriate for supernova distances inspired by recent 60 Fe data, and for a 20 pc supernova proposed to account for mass extinctions at the end-Devonian period. We examine the locations of the termination shock decelerating the solar wind and the heliopause that marks the boundary between the solar wind and supernova material. Pressure balance scaling holds, consistent with studies of other astrospheres. Solar wind anisotropy does not have an appreciable effect on shock geometry. We find that supernova explosions at 50 pc (95 pc) lead to heliopause locations at 16 au (23 au) when the forward shock arrives. Thus, the outer solar system was directly exposed to the blast, but the inner planets—including Earth—were not. This finding reaffirms that the delivery of supernova material to Earth is not from the blast plasma itself, but likely is from supernova dust grains. After the arrival of the forward shock, the weakening supernova blast will lead to a gradual rebound of the heliosphere, taking ∼few × 100 kyr to expand beyond 100 au. Prospects for future work are discussed. 

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4. Deep-Sea and Lunar Radioisotopes from Nearby Astrophysical Explosions

   https://doi.org/10.1146/annurev-nucl-011823-045541  

   Fields, Brian D.; Wallner, Anton (September 2023, Annual Review of Nuclear and Particle Science)

   Live (not decayed) radioisotopes on the Earth and Moon are messengers from recent nearby astrophysical explosions. Measurements of⁶⁰Fe in deep-sea samples, Antarctic snow, and lunar regolith reveal two pulses about 3 Myr and 7 Myr ago. Detection of²⁴⁴Pu in a deep-sea crust indicates a recent r-process event. We review the ultrasensitive accelerator mass spectrometry techniques that enable these findings. We then explore the implications for astrophysics, including supernova nucleosynthesis, particularly the r-process, as well as supernova dust production and the formation of the Local Bubble that envelops the Solar System. The implications go beyond nuclear physics and astrophysics to include studies of heliophysics, astrobiology, geology, and evolutionary biology. 

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5. Simulations of 60Fe entrained in ejecta from a near-Earth supernova: effects of observer motion

   https://doi.org/10.1093/mnras/stac327  

   Chaikin, Evgenii; Kaurov, Alexander A.; Fields, Brian D.; Correa, Camila A. (February 2022, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT Recent studies have shown that live (not decayed) radioactive 60Fe is present in deep-ocean samples, Antarctic snow, lunar regolith, and cosmic rays. 60Fe represents supernova (SN) ejecta deposited in the Solar system around $$3 \, \rm Myr$$ ago, and recently an earlier pulse $${\approx}7 \ \rm Myr$$ ago has been found. These data point to one or multiple near-Earth SN explosions that presumably participated in the formation of the Local Bubble. We explore this theory using 3D high-resolution smooth-particle hydrodynamical simulations of isolated SNe with ejecta tracers in a uniform interstellar medium (ISM). The simulation allows us to trace the SN ejecta in gas form and those eject in dust grains that are entrained with the gas. We consider two cases of diffused ejecta: when the ejecta are well-mixed in the shock and when they are not. In the latter case, we find that these ejecta remain far behind the forward shock, limiting the distance to which entrained ejecta can be delivered to ≈100 pc in an ISM with $$n_\mathrm{H}=0.1\,\, \rm cm^{-3}$$ mean hydrogen density. We show that the intensity and the duration of 60Fe accretion depend on the ISM density and the trajectory of the Solar system. Furthermore, we show the possibility of reproducing the two observed peaks in 60Fe concentration with this model by assuming two linear trajectories for the Solar system with 30-km s−1 velocity. The fact that we can reproduce the two observed peaks further supports the theory that the 60Fe signal was originated from near-Earth SNe. 

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