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The Production Rate of Type Ia Supernovae from Population III Stars


Основные понятия
Population III stars, the first generation of stars formed in the early universe, could be significant, even dominant, producers of Type Ia supernovae at high redshifts (z ≳ 6), potentially detectable by the James Webb Space Telescope.
Аннотация

Bibliographic Information:

Li, Z., Wang, L., Han, Z., & Chen, X. (2024). Type Ia Supernovae from First-generation Stars. arXiv preprint arXiv:2407.19357v2.

Research Objective:

This study investigates the possibility of Type Ia supernovae (SNe Ia) originating from Population III (Pop III) stars, the first generation of stars formed in the early universe. The authors aim to determine the production rate of such SNe Ia and assess the likelihood of their detection with the James Webb Space Telescope (JWST).

Methodology:

The researchers employ a combination of detailed stellar evolution modeling using the Modules for Experiments in Stellar Astrophysics (MESA) code and semi-analytic calculations to simulate the evolution of Pop III binary systems. They consider both the single degenerate (SD) and double degenerate (DD) channels for SNe Ia production. For the SD channel, they utilize the common envelope wind (CEW) model, while for the DD channel, they adopt a delay time distribution (DTD) similar to that of Pop I stars. The authors then incorporate these models into a cosmological framework, considering two representative cosmic star formation history (CSFH) models for Pop III stars.

Key Findings:

  • Pop III stars could produce a substantial number of SNe Ia at high redshifts, potentially becoming the dominant source at z ≳ 6.
  • Assuming an optimistic scenario and a bottom-heavy initial mass function (IMF) for Pop III stars, the JWST could detect ∼1 (2) SNe Ia from Pop III progenitors at z ≈ 4 (5) within a 3-year survey covering 300 arcmin2.
  • The same survey might observe over ∼400 SNe Ia at lower redshifts (z ≲ 2.5), but only about one would likely originate from Pop III stars.
  • Approximately ∼6 Pop III SNe Ia could be present within the same field of view at redshifts of 5 − 10.

Main Conclusions:

The study suggests that Pop III stars could be significant contributors to the SNe Ia rate at high redshifts. Observations of SNe Ia rates at z = 5 − 10 with the JWST could provide crucial constraints on the IMF of Pop III stars, offering valuable insights into the early universe's star formation processes.

Significance:

This research highlights the potential of SNe Ia as probes of the early universe and the nature of the first stars. Detecting and characterizing Pop III SNe Ia would provide crucial information about the early stages of cosmic evolution, metal enrichment, and the formation of the first galaxies.

Limitations and Future Research:

The study acknowledges limitations due to the simplified treatment of binary evolution and the assumed DTD for the DD channel. Future research incorporating detailed binary population synthesis calculations and exploring alternative IMFs for Pop III stars would refine the predictions and provide a more comprehensive understanding of Pop III SNe Ia.

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Статистика
The observed SNe Ia rates are about two times higher than those predicted by theoretical simulations. The minimum WD mass of CO WDs leading to SNe Ia is 0.9 M⊙. WDs with masses of 0.9−1.2 M⊙ have progenitor masses of about ∼3.7 −7.3 M⊙. The evolutionary timescale for WDs with masses of 0.9−1.2 M⊙ is about 3.86 × 10^7 −1.17 × 10^8 yr. Secondary stars that produce SNe Ia have masses in the range of 1.2−4.0 M⊙. The timescale for secondary stars with masses of 1.2−4.0 M⊙ is ∼1.2×10^8−3.4×10^9 yr. The JWST could detect ∼1 (2) SNe Ia from Pop III progenitors at z ≈ 4 (5) within a 3-year survey covering 300 arcmin2. The same survey might observe over ∼400 SNe Ia at lower redshifts (z ≲ 2.5). Approximately ∼6 Pop III SNe Ia could be present within the same field of view at redshifts of 5 − 10.
Цитаты

Ключевые выводы из

by Zhenwei Li, ... в arxiv.org 10-10-2024

https://arxiv.org/pdf/2407.19357.pdf
Type Ia Supernovae from First-generation Stars

Дополнительные вопросы

How might the detection of Pop III SNe Ia influence our understanding of the chemical evolution of the early universe?

Detecting Pop III SNe Ia would be revolutionary for our understanding of the early universe's chemical evolution. Here's how: Constraining the Pop III IMF: As the paper highlights, the rate of Pop III SNe Ia is highly sensitive to the Pop III initial mass function (IMF). A top-heavy IMF, producing mostly massive stars, would lead to a lower SN Ia rate compared to a bottom-heavy IMF that forms more low- and intermediate-mass stars. Observing these supernovae and measuring their rates at high redshifts would provide crucial constraints on the Pop III IMF. This, in turn, would illuminate the mass distribution of the first stars and their role in subsequent star formation. Tracing Early Metal Enrichment: Pop III stars, formed from metal-free primordial gas, were responsible for the initial stages of metal enrichment in the universe. SNe Ia are known to produce significant amounts of iron-peak elements. Detecting Pop III SNe Ia would offer a direct way to trace the production and dispersal of these metals in the early universe. This would refine our models of how the first galaxies and stars transitioned from a pristine state to one enriched with heavier elements. Understanding Early Galaxy Evolution: The rate and distribution of Pop III SNe Ia can provide insights into the environments where the first stars formed. Were they clustered in the first galaxies, or more sparsely distributed? The answers to these questions, informed by Pop III SN Ia observations, would shed light on the early stages of galaxy formation and evolution.

Could other astrophysical phenomena mimic the observational signatures of Pop III SNe Ia, and how can we differentiate between them?

Yes, several astrophysical phenomena can mimic the observational signatures of Pop III SNe Ia, particularly at high redshifts. Here are some potential impostors and ways to differentiate them: Superluminous Supernovae (SLSNe): These extremely bright explosions can have similar peak luminosities to SNe Ia. However, SLSNe generally exhibit much slower light curves and different spectral characteristics, particularly in the late-time nebular phase. Careful light curve analysis and spectroscopic follow-up observations can help distinguish between them. Active Galactic Nuclei (AGN): The accretion disks around supermassive black holes can also be incredibly luminous. However, AGN tend to show variability across a broader range of timescales compared to the more predictable light curves of SNe Ia. Additionally, AGN exhibit distinct spectral features associated with their accretion processes, which can be used for differentiation. Gravitationally Lensed SNe: Gravitational lensing by foreground galaxies can magnify the light from distant SNe, making them appear brighter and potentially mimicking Pop III SNe Ia. However, lensed SNe often appear as multiple images, and the lensing galaxy itself can be identified through deep imaging. Differentiation Strategies: High-resolution Imaging: Identifying multiple images or a lensing galaxy can rule out lensed SNe. Multi-wavelength Observations: Observing the transient across a wide range of wavelengths can reveal distinct spectral features that can help differentiate between SNe Ia and other phenomena like AGN or SLSNe. Light Curve Analysis: The characteristic light curve shape of SNe Ia, particularly the rise and fall times, can be used to distinguish them from other transients.

If Pop III stars are indeed significant producers of SNe Ia at high redshifts, what are the implications for the reionization history of the universe?

If Pop III stars are significant producers of SNe Ia at high redshifts, it could have intriguing implications for the reionization history of the universe: Delayed Reionization Contribution: SNe Ia, with their longer delay times compared to prompt events like core-collapse supernovae, would have contributed to the ionization of the intergalactic medium at later stages of reionization. This could mean that Pop III stars played a more extended role in reionization than previously thought, potentially shaping the ionization structure of the early universe. Metal Enrichment Feedback: The metals ejected by Pop III SNe Ia would have been dispersed into the intergalactic medium, affecting subsequent star formation. This metal enrichment could have influenced the transition from Pop III to Pop II star formation, impacting the overall reionization process. Observational Signatures: The increased metallicity from Pop III SNe Ia could leave observable imprints on the cosmic microwave background (CMB) through the Sunyaev-Zel'dovich effect. Future CMB observations might be able to detect these subtle signals, providing indirect evidence for the role of Pop III SNe Ia in reionization. However, it's important to note that the impact of Pop III SNe Ia on reionization is still uncertain and depends on various factors, including the Pop III IMF, star formation efficiency, and the escape fraction of ionizing photons from early galaxies.
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