SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2078394553> ?p ?o ?g. }

Showing items 1 to 100 of ±116 with 100 items per page.

W2078394553 endingPage "362" @default.
W2078394553 startingPage "323" @default.
W2078394553 abstract "In dealing with the G-dwarf problem in the solar neighbourhood, simple comoving models of chemical evolution are generalized on two respects, assuming that star formation occurs: (i) within discrete regions instead of a continuous interstellar medium, and (ii) via stochastic processes instead of a uniform generation, with the additional hypotheses: (iii) mass conservation, (iv) instantaneous recycling, and (v) instantaneous mixing within the system at the end of a fixed time step, in connection with identical regions. In the special case of the expected evolution, when the number of star-forming regions equals the expected value of the related, binomial distribution, the gas mass fraction shows an exponential time dependence, the oxygen mass fraction a linear time dependence, and the star formation rate (related to the system) a linear dependence on the gas mass fraction, i.e. the gas density, whatever the star formation rate (related to a region) may be, provided the corresponding parameters are independent of evolution. In addition, it is shown that the dependence of oxygen gas mass fraction on gas mass fraction remains unchanged with respect to a simple model. Two main classes of theoretical age-metallicity relation (TAMR) are analysed and discussed, according if the contribution to an assigned metallicity bin comes from long-lived stars which are born during all the, or only a fraction of, time steps. It is found that, under some simplifying assumptions, the theoretical, differential, G-dwarf metallicity distribution (TGD) has the same expression as in simple models, in connection with the main body of the TAMR. An application is made for the solar neighbourhood, and the input parameters are constrained to both the empirical age-metallicity relation (EAMR) and the empirical, differential, G-dwarf metallicity distribution (EGD). A different, power-law, initial mass function (IMF) is allowed during and after disk formation. A power-law steeper than the Salpeter IMF, which fits the Scalo IMF, is necessary to ensure a lower stellar mass limit above the stellar Jeans mass. An acceptable fit to the EAMR is provided by models where the ratio of oxygen yield, and lower stellar mass limit, during and after disk formation, range from about one half to about three halves. On the other hand, a fit to the EGD allows models where the IMF changes only slightly, or remains unchanged, during and after disk formation. Then a solution to the G-dwarf problem demands, in the light of the current model, nothing but an initial, substructured disk made of pre-enriched material, with same metallicity as the lower limit detected in G dwarfs belonging to the sample under consideration. Several runs are made in different situations, related to either constant number of regions or constant mass of a region, separately during and after disk formation. Significant statistical fluctuations are found when the number of regions is low enough, i.e. of the order of ten. A sharp peak exhibited by the EGD cannot be interpreted in terms of statistical fluctuations, in the context of the current model, unless about 3% of G dwarfs in the solar neighbourhood were born during a burst of star formation within quiescent regions. To avoid contradiction with both the TAMR and TGD, the above mentioned burst would have been occurred 2-4 Gyr ago in connection with a metallicity, Z/Z⊙ ≈ 0.5-0.6, consistent with both a chemical and kinematical transition observed in the disk." @default.
W2078394553 created "2016-06-24" @default.
W2078394553 creator A5034435823 @default.
W2078394553 date "2000-12-01" @default.
W2078394553 modified "2023-09-24" @default.
W2078394553 title "The G-dwarf problem in the solar neighbourhood: a statistical approach within a inhomogeneous, simple model" @default.
W2078394553 cites W1574217534 @default.
W2078394553 cites W1669919286 @default.
W2078394553 cites W1964400191 @default.
W2078394553 cites W1968297864 @default.
W2078394553 cites W1969174337 @default.
W2078394553 cites W1974560554 @default.
W2078394553 cites W1977241361 @default.
W2078394553 cites W1978769139 @default.
W2078394553 cites W1981543419 @default.
W2078394553 cites W1986010423 @default.
W2078394553 cites W1990925621 @default.
W2078394553 cites W1993301080 @default.
W2078394553 cites W1996227776 @default.
W2078394553 cites W2007490657 @default.
W2078394553 cites W2010389259 @default.
W2078394553 cites W2012861437 @default.
W2078394553 cites W2014282890 @default.
W2078394553 cites W2015295900 @default.
W2078394553 cites W2016561491 @default.
W2078394553 cites W2016561923 @default.
W2078394553 cites W2019149140 @default.
W2078394553 cites W2029659558 @default.
W2078394553 cites W2030777190 @default.
W2078394553 cites W2032471326 @default.
W2078394553 cites W2039982428 @default.
W2078394553 cites W2041604411 @default.
W2078394553 cites W2052670534 @default.
W2078394553 cites W2053321229 @default.
W2078394553 cites W2060415148 @default.
W2078394553 cites W2063991749 @default.
W2078394553 cites W2066253188 @default.
W2078394553 cites W2070760985 @default.
W2078394553 cites W2073123016 @default.
W2078394553 cites W2074803207 @default.
W2078394553 cites W2076995400 @default.
W2078394553 cites W2078735378 @default.
W2078394553 cites W2080900832 @default.
W2078394553 cites W2083323088 @default.
W2078394553 cites W2084886495 @default.
W2078394553 cites W2086303799 @default.
W2078394553 cites W2087227925 @default.
W2078394553 cites W2089017458 @default.
W2078394553 cites W2090985798 @default.
W2078394553 cites W2094176154 @default.
W2078394553 cites W2095358030 @default.
W2078394553 cites W2096612101 @default.
W2078394553 cites W2106102452 @default.
W2078394553 cites W2106136195 @default.
W2078394553 cites W2153258189 @default.
W2078394553 cites W2155457133 @default.
W2078394553 cites W2163157792 @default.
W2078394553 cites W2994765829 @default.
W2078394553 cites W3015346111 @default.
W2078394553 cites W3100334026 @default.
W2078394553 cites W3102694770 @default.
W2078394553 cites W3105156727 @default.
W2078394553 cites W3126103517 @default.
W2078394553 cites W3166933445 @default.
W2078394553 cites W4239039511 @default.
W2078394553 doi "https://doi.org/10.1002/1521-3994(200012)321:5/6<323::aid-asna323>3.0.co;2-c" @default.
W2078394553 hasPublicationYear "2000" @default.
W2078394553 type Work @default.
W2078394553 sameAs 2078394553 @default.
W2078394553 citedByCount "3" @default.
W2078394553 countsByYear W20783945532017 @default.
W2078394553 crossrefType "journal-article" @default.
W2078394553 hasAuthorship W2078394553A5034435823 @default.
W2078394553 hasConcept C11413529 @default.
W2078394553 hasConcept C116628846 @default.
W2078394553 hasConcept C121332964 @default.
W2078394553 hasConcept C121864883 @default.
W2078394553 hasConcept C125857072 @default.
W2078394553 hasConcept C150846664 @default.
W2078394553 hasConcept C156273044 @default.
W2078394553 hasConcept C33923547 @default.
W2078394553 hasConcept C44870925 @default.
W2078394553 hasConcept C97355855 @default.
W2078394553 hasConcept C99465377 @default.
W2078394553 hasConceptScore W2078394553C11413529 @default.
W2078394553 hasConceptScore W2078394553C116628846 @default.
W2078394553 hasConceptScore W2078394553C121332964 @default.
W2078394553 hasConceptScore W2078394553C121864883 @default.
W2078394553 hasConceptScore W2078394553C125857072 @default.
W2078394553 hasConceptScore W2078394553C150846664 @default.
W2078394553 hasConceptScore W2078394553C156273044 @default.
W2078394553 hasConceptScore W2078394553C33923547 @default.
W2078394553 hasConceptScore W2078394553C44870925 @default.
W2078394553 hasConceptScore W2078394553C97355855 @default.
W2078394553 hasConceptScore W2078394553C99465377 @default.
W2078394553 hasIssue "5-6" @default.
W2078394553 hasLocation W20783945531 @default.
W2078394553 hasOpenAccess W2078394553 @default.