About 4.6 billion years ago, some event disturbed a cloud of gas and dust, triggering the gravitational collapse that led to the formation of the solar system. A core-collapse supernova, whose shock wave is capable of compressing such a cloud, is an obvious candidate for the initiating event. This hypothesis can be tested because supernovae also produce telltale patterns of short-lived radionuclides, which would be preserved today as isotopic anomalies. Previous studies of the forensic evidence have been inconclusive, finding a pattern of isotopes differing from that produced in conventional supernova models. Here we argue that these difficulties either do not arise or are mitigated if the initiating supernova was a special type, low in mass and explosion energy. Key to our conclusion is the demonstration that short-lived 10Be can be readily synthesized in such supernovae by neutrino interactions, while anomalies in stable isotopes are suppressed.
Nearly four decades ago Cameron and Truran1 suggested that the formation of our solar system (SS) might have been due to a single core-collapse supernova (CCSN) whose shock wave triggered the collapse of a nearby interstellar cloud. They recognized that forensic evidence of such an event would be found in CCSN-associated short-lived (≲10 Myr) radionuclides (SLRs) that would decay, but leave a record of their existence in isotopic anomalies. Their suggestion was in fact stimulated by observed meteoritic excesses in 26Mg (ref. 2), the daughter of the extinct SLR 26Al with a lifetime of Myr. The inferred value of 26Al/27Al in the early SS, orders of magnitude higher than the Galactic background, requires a special source3.
While simulations support the thesis that a CCSN shock wave can trigger SS formation and inject SLRs into the early SS4,5,6, detailed modelling of CCSN nucleosynthesis and an accumulation of data on extinct radionuclides have led to a confusing and conflicting picture3,7. CCSNe of ≳15 solar masses are a major source of stable isotopes such as 24Mg, 28Si and 40Ca. The contributions from a single CCSN in this mass range combined with the dilution factor indicated by simulations4,5,6 would have caused large shifts in ratios of stable isotopes that are not observed3. A second problem concerns the relative production of key SLRs: such a CCSN source grossly overproduces 53Mn and 60Fe (ref. 3), while producing (relatively) far too little of 10Be. Although the overproduction of 53Mn and 60Fe can plausibly be mitigated by the fallback of inner CCSN material, preventing the ejection of these two SLRs7,8, the required fallback must be extremely efficient in high-mass CCSNe.
Here we show that the above difficulties with the CCSN trigger hypothesis can be removed or mitigated, if the CCSN mass was ≲12. The structure of a low-mass CCSN progenitor differs drastically from that of higher-mass counterparts, being compact with much thinner processed shells. Given the CCSN trigger hypothesis, we argue that the stable isotopes alone demand such a progenitor. But in addition, this assumption addresses several other problems noted above. First, we show the yields of 53Mn and 60Fe are reduced by an order of magnitude or more in low-mass CCSNe, making the fallback required to bring the yields into agreement with the data much more plausible. Second, we show that the mechanism by which CCSNe produce 10Be, the neutrino spallation process 12C(ν,ν′pp)10Be, differs from other SLR production mechanisms in that the yield of 10Be remains high as the progenitor mass is decreased. Consequently we find that an 11.8 model can produce the bulk of the 10Be inventory in the early SS without overproducing other SLRs. We conclude that among possible CCSN triggers, a low-mass one is demanded by the data on both stable isotopes and SLRs.
It has been commonly thought that 10Be is not associated with stellar sources, originating instead only from spallation of carbon and oxygen in the interstellar medium (ISM) by cosmic rays (CRs9) or irradiation of the early SS material by solar energetic particles (SEPs10,11) associated with activities of the proto-Sun. It was noted in Yoshida et al.12 that 10Be can be produced by neutrino interactions in CCSNe, but the result was presented for a single model and no connection to meteoritic data was made. Further, that work adopted an old rate for the destruction reaction 10Be(α,n)13C that is orders of magnitude larger than currently recommended13, and therefore, greatly underestimated the 10Be yield.
10Be has been observed in the form of a 10B excess in a range of meteoritic samples. Significant variations across the samples suggest that multiple sources might have contributed to its inventory in the early SS14,15,16,17,18,19. Calcium-aluminum-rich inclusions (CAIs) with 26Al/27Al close to the canonical value were found to have significantly higher 10Be/9Be than CAIs with fractionation and unidentified nuclear isotope effects (FUN-CAIs), which also have 26Al/27Al much less than the canonical value18. As FUN-CAIs are thought to have formed earlier than canonical CAIs, it has been suggested18 that the protosolar cloud was seeded with 10Be/9Be∼3 × 10−4, the level observed in FUN-CAIs, by for example, trapping Galactic CRs9, and that the significantly higher 10Be/9Be values in canonical CAIs were produced later by SEPs10,11.
A recent study20 showed that trapping Galactic CRs led to little 10Be enrichment of the protosolar cloud and long-term production by Galactic CRs could only provide 10Be/9Be≲1.3 × 10−4. Instead, CRs from either a large number of CCSNe or a single special CCSN were proposed to account for 10Be/9Be∼3 × 10−4. While this pre-enrichment scenario is plausible, it depends on many details of CCSN remnant evolution and CR production and interaction. Similarly, further production of 10Be by SEPs must have occurred at some level, but the actual contributions are sensitive to the composition, spectra and irradiation history of SEPs as well as the composition of the irradiated gas and solids10,11,21, all of which are rather uncertain. In view of both the data and uncertainties in CR and SEP models, we consider it reasonable that a low-mass CCSN provided the bulk of the 10Be inventory in the early SS while still allowing significant contributions from CRs and SEPs. Specifically, we find that such a CCSN can account for 10Be/9Be=(7.5±2.5) × 10−4 typical of the canonical CAIs22. Following the presentation of our detailed results, we will discuss an overall scenario to account for 10Be and other SLRs based on our proposed low-mass CCSN trigger and other sources.
We have calculated CCSN nucleosynthesis for solar-composition progenitors in the mass range of 11.8–30. Each star was evolved to core collapse, using the most recent version of the 1D hydrodynamic code KEPLER23,24. The subsequent explosion was simulated by driving a piston from the base of the oxygen shell into the collapsing progenitor. Piston velocities were selected to produce explosion energies of 0.1, 0.3, 0.6 and 1.2 B (1 B=1051 ergs) for the 11.8–12, 14, 16 and 18–30 models, respectively, to match results from recent CCSN simulations25,26. The material inside the initial radius of the piston was allowed to fall immediately onto the protoneutron star forming at the core. In our initial calculations, shown in Fig. 1 and labelled Case 1 in Table 1, we assume all material outside the piston is ejected. Neutrino emission was modelled by assuming Fermi-Dirac spectra with chemical potentials μ=0, fixed temperatures MeV and MeV, and luminosities decreasing exponentially from an initial value of 16.7 B s−1 per species, governed by a time constant of ∼3 s. This treatment is consistent with detailed neutrino transport calculations27 as well as supernova 1987A observations28. A full reaction network was used to track changes in composition during the evolution and explosion of each star, including neutrino rates taken from Heger et al.29.
Figure 1 shows the yields normalized to the 11.8 model as functions of the progenitor mass for stable isotopes 12C, 16O, 24Mg, 28Si, 40Ca and 56Fe as well as SLRs 10Be, 41Ca, 53Mn, 60Fe and 107Pd. It can be seen that except for 10Be, the yields of all other isotopes increase sharply for CCSNe of 14–30. Therefore, a high-mass CCSN trigger is problematic, generating unacceptably large shifts in ratios of stable isotopes and overproducing SLRs such as 53Mn and 60Fe (ref. 3). Fallback of ≳1 of inner material in such CCSNe was invoked in Takigawa et al.8 to account for the data on the SLRs 26Al, 41Ca, 53Mn and 60Fe. Using our models (Supplementary Table 1), we find that similar fallback scenarios and dilution factors are required but the problem with stable isotopes persists (Supplementary Discussion). In contrast, even for Case 1 without fallback, the yields of the 11.8 model (Supplementary Tables 2 and 3) are consistent with meteoritic constraints for all major stable isotopes (Supplementary Discussion). We focus on the production of SLRs by this model below.
Figure 1 shows that in contrast to other isotopes, the 10Be yield from 12C via 12C(ν, ν′pp)10Be is relatively insensitive to progenitor mass. This reflects the compensating effects of higher C-zone masses but lower neutrino fluxes (larger C-zone radii) in more massive stars (see Supplementary Discussion for more on SLR production). Our demonstration here that 10Be is a ubiquitous CCSN product of neutrino-induced nucleosynthesis consequently allows us to attribute this SLR to a low-mass CCSN, explaining its abundance level in canonical CAIs, while achieving overall consistency with the data on other SLRs coproduced by other mechanisms in the CCSN. More quantitatively, let R denote a given SLR, I its stable reference isotope, YR the total mass yield of R from the CCSN, and f the fraction of the yield that was incorporated into each of the protosolar cloud (that is, the dilution factor). The number ratio of R to I in the early SS due to this CCSN is
where AR and AI are the mass numbers of R and I, is the solar mass fraction of I30, Δ is the time between the CCSN explosion and incorporation of R into early SS solids, and is the lifetime of R.
Table 1 gives the mass yields of 10Be, 26Al, 36Cl, 41Ca, 53Mn, 60Fe, 107Pd, 135Cs, 182Hf and 205Pb for the 11.8 model. A comparison of equation (1) to the observed value, including uncertainties22,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45, yields a band of allowed f and Δ for each SLR. Simultaneous explanation of SLRs then requires the corresponding bands to overlap. Figure 2 shows a region of concordance for 10Be, 41Ca and 107Pd. This fixes f and Δ, allowing us to estimate the contributions from the 11.8 CCSN to other SLRs. The Case 1 contributions to 26Al, 36Cl, 53Mn, 60Fe, 135Cs, 182Hf and 205Pb in Table 1 correspond to f∼5 × 10−4 and Δ∼1 Myr, the approximate best-fit point indicated by the filled circle in Fig. 2.
The slow-neutron-capture (s) process product 182Hf is of special interest, as the yield of this SLR is sensitive to the β-decay rate of 181Hf, which may be affected by thermally populated low-lying excited states under stellar conditions. We treat the excited-state contribution as an uncertainty46, allowing the rate to vary between the laboratory value and the theoretical estimate of ref. 47 with excited states. (The latter is numerically close to updated estimates with uncertainties46.) The yield obtained with the laboratory rate accounts for almost all of the 182Hf in the early SS. This removes a conflict with data on the SLR 129I that arises when 182Hf is attributed to the rapid neutron-capture (r) process46,48.
Role of fallback
The Case 1 results of Table 1 are consistent with the meteoritic data on 26Al, 36Cl, 135Cs, 182Hf and 205Pb, as the contributions do not exceed the measured values. In contrast, although the production of 53Mn and 60Fe is greatly reduced in low-mass CCSNe, the 53Mn contribution remains a factor of 60 too large while 60Fe is compatible only with the larger of the two observed values (Table 1). Both of these SLRs originate from zones deep within the 11.8 star: 53Mn is produced in the innermost 10−2 of the shocked material, while ∼90% of the 60Fe is associated with the innermost 0.12. Because of the low explosion energy used here based on simulations26, the expected fallback of the innermost shocked zones onto the protoneutron star49 provides a natural explanation for the discrepancies: most of the produced 53Mn and, possibly, 60Fe is not ejected. In Case 2 of Table 1, where only 1.5% of the innermost 1.02 × 10−2 is ejected, 53Mn/55Mn is reduced to its measured value (6.28±0.66) × 10−6 (ref. 38), while other SLR contributions are largely unaffected. In Case 3, where only 1.5% of the innermost 0.116 is ejected, additional large reductions (a factor of ∼10) are found for 60Fe and 182Hf, accompanied by smaller decreases (a factor of ∼2) in 26Al, 36Cl, 135Cs and 205Pb.
Case 3 represents the limit of reducing 53Mn and 60Fe without affecting the concordance among 10Be, 41Ca and 107Pd (Supplementary Fig. 1; Supplementary Discussion). Were the lower observed value for 60Fe (ref. 39) proven correct, we would have to either reduce its yield by examining the significant nuclear and stellar physics uncertainties50,51 or use even more substantial fallback and reconsider the low-mass CCSN contributions to SLRs. Because of the correlated effects of fallback on 60Fe and 182Hf, more fallback would also rule out an attractive explanation for the latter, as described above. Note that the fallback assumed for Cases 2 and 3 is far below that invoked for high-mass CCSNe in Takigawa et al.8 to account for 26Al, 41Ca, 53Mn and the higher observed value of 60Fe.
If, however, the higher 60Fe value40 is correct, then a plausible scenario like Case 2, where SS formation was triggered by a low-mass CCSN with modest fallback, would be in reasonable agreement with the data on 10Be, 41Ca, 53Mn, 60Fe and 107Pd. The nuclear forensics, notably the rapidly decaying 41Ca, determines the delay between the CCSN explosion and incorporation of SLRs into early SS solids, Δ∼1 Myr. The deduced fraction of CCSN material injected into the protosolar cloud, f∼5 × 10−4, is consistent with estimates based on simulations of ejecta interacting with dense gas clouds4,5,6 (Supplementary Discussion). There is also an implicit connection to the CCSN explosion energy, which influences fallback in hydrodynamic models.
In addition to neutrino-induced production, a low-mass CCSN can make 10Be through CRs associated with its remnant evolution20. However, the yield of this second source is modest (Supplementary Discussion). The net yield in the ISM trapped within the remnant is limited by the amount of this ISM. Production within the general protosolar cloud during its initial contact with the remnant (that is, before thorough mixing of the injected material) would also be expected, and the yield could possibly account for 10Be/9Be∼3 × 10−4 in FUN-CAIs20. However, FUN-CAIs are rare, and their 10Be inventory may be more consistent with local production by the CCSN CRs. Taking the net CR contribution averaged over the protosolar cloud to be 10Be/9Be∼10−4, a value that we argue is more consistent with long-term production by Galactic CRs20, we add the neutrino-produced 10Be/9Be∼(5.2–6.4) × 10−4 (Table 1) from the CCSN to obtain 10Be/9Be∼(6.2–7.4) × 10−4, which is in accord with 10Be/9Be=(7.5±2.5) × 10−4 observed in canonical CAIs. In general, we consider that neutrino-induced production provided the baseline 10Be inventory in these samples and the observed variations14,16,18,19 can be largely attributed to local production by SEPs.
Our proposal that a low-mass CCSN trigger provided the bulk of the 10Be inventory in the early SS has several important features: (1) the relevant neutrino and CCSN physics is known reasonably well, and the uncertainty in the 10Be yield is estimated here to be within a factor of ∼2; (2) the production of both 10Be and 41Ca is in agreement with observations36,37, a result difficult to achieve by SEPs19; and (3) the yield pattern of Li, Be and B isotopes (Supplementary Table 4) is distinctive, with predominant production of 7Li and 11B and differing greatly from patterns of production by CRs and SEPs, so that precise meteoritic data might provide distinguishing tests (Supplementary Discussion).
We emphasize that while 53Mn and 60Fe production is greatly reduced in a low-mass CCSN, some fallback is still required to explain the meteoritic data. The fallback solution works well for 53Mn (Table 1). When somewhat different meteoritic values of 53Mn/55Mn (refs 52, 53) are used, only the ejected fractions of the innermost shocked material need to be adjusted accordingly. The case of 60Fe is more complicated. The meteoritic measurements are difficult, especially in view of a recent study showing the mobility of Fe and Ni in the relevant samples54. Another recent study gave 5 × 10−8≲60Fe/56Fe≲2.6 × 10−7 (ref. 55), which may be accounted for by Case 3 of our model (Table 1). However, were 60Fe/56Fe∼10−8 (ref. 39), currently preferred by many workers, to be confirmed, we would have to conclude that either the present 60Fe yield of the low-mass CCSN is wrong or its contributions to SLRs must be reconsidered.
Several other issues with our proposed low-mass CCSN trigger merit discussion. Table 1 shows that such a CCSN underproduces 26Al, 36Cl and 135Cs to varying degrees. We consider that the ISM swept up by the CCSN shock wave before triggering the collapse of the protosolar cloud might have been enriched with 26Al by nearby massive stars. To avoid complications with 53Mn and 60Fe, we propose that these stars might have exploded only weakly or not at all49, but contributed 26Al through their winds. The total amount of swept-up 26Al needed to be ∼10−5 (see Table 1), which could have been provided by winds from stars of ≳3550, possibly in connection with an evolving giant molecular cloud56. Winds from massive stars may also have contributed to 41Ca and 135Cs (ref. 57). However, the wind contribution to 41Ca might be neglected given the rapid decay of this SLR over the interval of ∼1 Myr between the onset of collapse of the protosolar cloud and incorporation of SLRs into early SS solids (Supplementary Discussion). We agree with previous studies that 36Cl was probably produced by SEPs after most of the initial 26Al had decayed34,35. The corresponding late irradiation would not have caused problematic coproduction of other SLRs, especially 10Be, 26Al and 53Mn, if it occurred in a reservoir enriched with volatile elements such as chlorine, a major target for producing 36Cl (ref. 35).
Our calculations do not include nucleosynthesis in the neutrino-heated ejecta from the protoneutron star, where some form of the r process may take place58,59. This is a potential source of the SLR 129I. As emphasized above, a low-mass CCSN would alter the SS ratios of stable isotopes of for example, Mg, Si, Ca and Fe only at levels of ≲1% (Supplementary Discussion), consistent with meteoritic constraints3. Nonetheless, Cases 2 and 3 with fallback would produce anomalies in 54Cr, 58Fe and 64Ni at levels of ∼10−3 as observed in meteorites (Supplementary Discussion). As there are few satisfactory explanations of these anomalies60, this provides circumstantial support for the fallback scenario required by the 53Mn and 60Fe data.
We conclude that a low-mass CCSN is a promising trigger for SS formation. Such a trigger is plausible because the lifetime of ∼20 Myr for the CCSN progenitor is compatible with the duration of star formation in giant molecular clouds61. Further progress depends on resolving discrepancies in 60Fe abundance determinations, clarifying the nuclear physics of 181Hf decay, and studying the evolution of additional low-mass CCSN progenitors and their explosion, especially quantifying fallback through multi-dimensional models. In addition, the overall scenario proposed here to explain the SLRs in the early SS requires comprehensive modelling of 26Al enrichment by winds from massive stars in an evolving giant molecular cloud, evolution of a low-mass CCSN remnant and the resulting CR production and interaction, and irradiation by SEPs associated with activities of the proto-Sun. Finally, tests of the low-mass CCSN trigger by precise measurements of Li, Be and B isotopes in meteorites are highly desirable (Supplementary Discussion).
The data that support the findings of this study are available from the corresponding author upon reasonable request.
How to cite this article: Banerjee, P. et al. Evidence from stable isotopes and 10Be for solar system formation triggered by a low-mass supernova. Nat. Commun. 7, 13639 doi: 10.1038/ncomms13639 (2016).
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Cameron, A. G. W. & Truran, J. W. The supernova trigger for formation of the solar system. Icarus 30, 447–461 (1977).
Lee, T., Papanastassiou, D. A. & Wasserburg, G. J. Correction [to ‘Demonstration of 26Mg excess in Allende and evidence for 26Al’]. Geophys. Res. Lett. 3, 109–112 (1976).
Wasserburg, G. J., Busso, M., Gallino, R. & Nollett, K. M. Short-lived nuclei in the early solar system: possible AGB sources. Nucl. Phys. A 777, 5–69 (2006).
Boss, A. P. & Keiser, S. A. Who pulled the trigger: a supernova or an asymptotic giant branch star? Astrophy. J. 717, L1–L5 (2010).
Boss, A. P. & Keiser, S. A. Triggering collapse of the presolar dense cloud core and injecting short-lived radioisotopes with a shock wave. III. Rotating three-dimensional cloud cores. Astrophys. J. 788, 20 (2014).
Boss, A. P. & Keiser, S. A. Triggering collapse of the presolar dense cloud core and injecting short-lived radioisotopes with a shock wave. IV. Effects of rotational axis orientation. Astrophys. J. 809, 103 (2015).
Meyer, B. S. & Clayton, D. D. Short-lived radioactivities and the birth of the sun. Space Sci. Rev. 92, 133–152 (2000).
Takigawa, A. et al. Injection of short-lived radionuclides into the early solar system from a faint supernova with mixing fallback. Astrophys. J. 688, 1382–1387 (2008).
Desch, S. J., Connolly, H. C. Jr & Srinivasan, G. An interstellar origin for the beryllium 10 in calcium-rich, aluminum-rich inclusions. Astrophys. J. 602, 528–542 (2004).
Gounelle, M. et al. Extinct radioactivities and protosolar cosmic rays: self-shielding and light elements. Astrophys. J. 548, 1051–1070 (2001).
Gounelle, M. et al. The irradiation origin of beryllium radioisotopes and other short-lived radionuclides. Astrophys. J. 640, 1163–1170 (2006).
Yoshida, T. et al. Neutrino-nucleus reaction cross sections for light element synthesis in supernova explosions. Astrophys. J. 686, 448–466 (2008).
Cyburt, R. H. et al. The JINA REACLIB database: its recent updates and impact on type-I X-ray bursts. Astrophys. J. Suppl. Ser. 189, 240–252 (2010).
McKeegan, K. D., Chaussidon, M. & Robert, F. Incorporation of short-lived 10Be in a calcium-aluminum-rich inclusion from the Allende meteorite. Science 289, 1334–1337 (2000).
Marhas, K. K., Goswami, J. N. & Davis, A. M. Short-lived nuclides in hibonite grains from Murchison: evidence for solar system evolution. Science 298, 2182–2185 (2002).
MacPherson, G. J., Huss, G. R. & Davis, A. M. Extinct 10Be in Type A calcium-aluminum-rich inclusions from CV chondrites. Geochim. Cosmochim. Acta 67, 3165–3179 (2003).
Liu, M.-C., Nittler, L. R., Alexander, C. M. O. & Lee, T. Lithium-beryllium-boron isotopic compositions in meteoritic hibonite: implications for origin of 10Be and early solar system irradiation. Astrophys. J. 719, L99–L103 (2010).
Wielandt, D. et al. Evidence for multiple sources of 10Be in the early solar system. Astrophys. J. 748, L25 (2012).
Srinivasan, G. & Chaussidon, M. Constraints on 10Be and 41Ca distribution in the early solar system from 26Al and 10Be studies of Efremovka CAIs. Earth Planet. Sci. Lett. 374, 11–23 (2013).
Tatischeff, V., Duprat, J. & de Séréville, N. Light-element nucleosynthesis in a molecular cloud interacting with a supernova remnant and the origin of beryllium-10 in the protosolar nebula. Astrophys. J. 796, 124 (2014).
Duprat, J. & Tatischeff, V. Energetic constraints on in situ production of short-lived radionuclei in the early solar system. Astrophys. J. 671, L69–L72 (2007).
Dauphas, N. & Chaussidon, M. A perspective from extinct radionuclides on a young stellar object: the sun and its accretion disk. Annu. Rev. Earth Planet. Sci. 39, 351–386 (2011).
Weaver, T. A., Zimmerman, G. B. & Woosley, S. E. Presupernova evolution of massive stars. Astrophys. J. 225, 1021–1029 (1978).
Rauscher, T., Heger, A., Hoffman, R. D. & Woosley, S. E. Hydrostatic and explosive nucleosynthesis in massive stars using improved nuclear and stellar physics. Nucl. Phys. A 718, 463–465 (2003).
Bruenn, S. W. et al. Axisymmetric ab initio core-collapse supernova simulations of 12–25 stars. Astrophys. J. 767, L6 (2013).
Melson, T., Janka, H.-T. & Marek, A. Neutrino-driven supernova of a low-mass iron-core progenitor boosted by three-dimensional turbulent convection. Astrophys. J. 801, L24 (2015).
Müller, B. & Janka, H.-T. A new multi-dimensional general relativistic neutrino hydrodynamics code for core-collapse supernovae. IV. The neutrino signal. Astrophys. J. 788, 82 (2014).
Yüksel, H. & Beacom, J. F. Neutrino spectrum from SN 1987A and from cosmic supernovae. Phys. Rev. D 76, 083007 (2007).
Heger, A. et al. Neutrino nucleosynthesis. Phys. Lett. B 606, 258–264 (2005).
Asplund, M., Grevesse, N., Sauval, A. J. & Scott, P. The chemical composition of the sun. Annu. Rev. Astron. Astrophys. 47, 481–522 (2009).
Davis, A. M. & McKeegan, K. D. In Meteorites and Cosmochemical Processes, Treatise of Geochemistry vol. 1, 361–395Elsevier (2014).
Jacobsen, B. et al. 26Al-26Mg and 207Pb-206Pb systematics of Allende CAIs: canonical solar initial 26Al/27Al ratio reinstated. Earth Planet. Sci. Lett. 272, 353–364 (2008).
Lin, Y., Guan, Y., Leshin, L. A., Ouyang, Z. & Wang, D. Short-lived chlorine-36 in a Ca- and Al-rich inclusion from the Ningqiang carbonaceous chondrite. Proc. Natl Acad. Sci. USA 102, 1306–1311 (2005).
Hsu, W., Guan, Y., Leshin, L. A., Ushikubo, T. & Wasserburg, G. J. A late episode of irradiation in the early solar system: evidence from extinct 36Cl and 26Al in meteorites. Astrophys. J. 640, 525–529 (2006).
Jacobsen, B. et al. Formation of the short-lived radionuclide 36Cl in the protoplanetary disk during late-stage irradiation of a volatile-rich reservoir. Astrophy. J. 731, L28 (2011).
Ito, M., Nagasawa, H. & Yurimoto, H. A study of Mg and K isotopes in Allende CAIs: implications to the time scale for the multiple heating processes. Meteorit. Planet. Sci. 41, 1871–1881 (2006).
Liu, M.-C., Chaussidon, M., Srinivasan, G. & McKeegan, K. D. A lower initial abundance of short-lived 41Ca in the early solar system and its implications for solar system formation. Astrophys. J. 761, 137 (2012).
Trinquier, A., Birck, J.-L., Allègre, C. J., Göpel, C. & Ulfbeck, D. 53Mn-53Cr systematics of the early solar system revisited. Geochim. Cosmochim. Acta 72, 5146–5163 (2008).
Tang, H. & Dauphas, N. Low 60Fe abundance in Semarkona and Sahara 99555. Astrophys. J. 802, 22 (2015).
Mishra, R. K. & Goswami, J. N. Fe-Ni and Al-Mg isotope records in UOC chondrules: plausible stellar source of 60Fe and other short-lived nuclides in the early Solar System. Geochim. Cosmochim. Acta 132, 440–457 (2014).
Schönbächler, M., Carlson, R. W., Horan, M. F., Mock, T. D. & Hauri, E. H. Silver isotope variations in chondrites: volatile depletion and the initial 107Pd abundance of the solar system. Geochim. Cosmochim. Acta 72, 5330–5341 (2008).
Hidaka, H., Ohta, Y., Yoneda, S. & DeLaeter, J. R. Isotopic search for live 135Cs in the early solar system and possibility of 135Cs-135Ba chronometer. Earth Planet. Sci. Lett. 193, 459–466 (2001).
Burkhardt, C. et al. Hf-W mineral isochron for Ca,Al-rich inclusions: age of the solar system and the timing of core formation in planetesimals. Geochim. Cosmochim. Acta 72, 6177–6197 (2008).
Nielsen, S. G., Rehkämper, M. & Halliday, A. N. Large thallium isotopic variations in iron meteorites and evidence for lead-205 in the early solar system. Geochim. Cosmochim. Acta 70, 2643–2657 (2006).
Baker, R. G. A., Schönbächler, M., Rehkämper, M., Williams, H. M. & Halliday, A. N. The thallium isotope composition of carbonaceous chondrites—New evidence for live 205Pb in the early solar system. Earth Planet. Sci. Lett. 291, 39–47 (2010).
Lugaro, M. et al. Stellar origin of the 182Hf cosmochronometer and the presolar history of solar system matter. Science 345, 650–653 (2014).
Takahashi, K. & Yokoi, K. Beta-decay rates of highly ionized heavy atoms in stellar interiors. At. Data Nucl. Data Tables 36, 375–409 (1987).
Wasserburg, G. J., Busso, M. & Gallino, R. Abundances of actinides and short-lived nonactinides in the interstellar medium: diverse supernova sources for the r-processes. Astrophys. J. 466, L109–L113 (1996).
Zhang, W., Woosley, S. E. & Heger, A. Fallback and black hole production in massive stars. Astrophys. J. 679, 639–654 (2008).
Limongi, M. & Chieffi, A. The nucleosynthesis of 26Al and 60Fe in solar metallicity stars extending in mass from 11 to 120 : the hydrostatic and explosive contributions. Astrophys. J. 647, 483–500 (2006).
Woosley, S. E. & Heger, A. Nucleosynthesis and remnants in massive stars of solar metallicity. Phys. Rep. 442, 269–283 (2007).
Nyquist, L. E., Kleine, T., Shih, C.-Y. & Reese, Y. D. The distribution of short-lived radioisotopes in the early solar system and the chronology of asteroid accretion, differentiation, and secondary mineralization. Geochim. Cosmochim. Acta 73, 5115–5136 (2009).
Yamashita, K., Maruyama, S., Yamakawa, A. & Nakamura, E. 53Mn-53Cr chronometry of CB chondrite: evidence for uniform distribution of 53Mn in the early solar system. Astrophy. J. 723, 20–24 (2010).
Telus, M. et al. Mobility of iron and nickel at low temperatures: implications for 60Fe-60Ni systematics of chondrules from unequilibrated ordinary chondrites. Geochim. Cosmochim. Acta 178, 87–105 (2016).
Telus, M., Huss, G. R., Nagashima, K., Ogliore, R. C. & Tachibana, S. In Lunar and Planetary Science Conference vol. 47, 1816 Lunar and Planetary Institute (2016).
Vasileiadis, A., Nordlund, Å. & Bizzarro, M. Abundance of 26Al and 60Fe in evolving giant molecular clouds. Astrophys. J. 769, L8 (2013).
Arnould, M., Goriely, S. & Meynet, G. The production of short-lived radionuclides by new non-rotating and rotating Wolf-Rayet model stars. Astron. Astrophys. 453, 653–659 (2006).
Woosley, S. E., Wilson, J. R., Mathews, G. J., Hoffman, R. D. & Meyer, B. S. The r-process and neutrino-heated supernova ejecta. Astrophys. J. 433, 229–246 (1994).
Wanajo, S., Janka, H.-T. & Müller, B. Electron-capture supernovae as the origin of elements beyond iron. Astrophys. J. 726, L15 (2011).
Wasserburg, G. J., Trippella, O. & Busso, M. Isotope anomalies in the Fe-group elements in meteorites and connections to nucleosynthesis in AGB stars. Astrophys. J. 805, 7 (2015).
Murray, N. Star formation efficiencies and lifetimes of giant molecular clouds in the Milky Way. Astrophys. J. 729, 133 (2011).
We acknowledge helpful discussions with Bernhard Müller and the late Jerry Wasserburg. We thank Takashi Yoshida for communications regarding ref. 12. This work was supported in part by the US DOE [DE-FG02-87ER40328 (UM), DE-SC00046548 (Berkeley), and DE-AC02-98CH10886 (LBL)], the US NSF [PHY-1430152 (JINA-CEE)], and ARC Future Fellowship FT120100363 (AH).
The authors declare no competing financial interests.
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Banerjee, P., Qian, YZ., Heger, A. et al. Evidence from stable isotopes and 10Be for solar system formation triggered by a low-mass supernova. Nat Commun 7, 13639 (2016). https://doi.org/10.1038/ncomms13639