Generalized uncertainty principle and burning stars

Moradpour, H.; Ziaie, A. H.; Sadeghnezhad, N.; Ghasemi, A.

doi:10.3389/fspas.2022.936352

BRIEF RESEARCH REPORT article

Front. Astron. Space Sci., 09 September 2022

Sec. High-Energy and Astroparticle Physics

Volume 9 - 2022 | https://doi.org/10.3389/fspas.2022.936352

This article is part of the Research Topic Generalized Uncertainty Relations: Existing Paradigms and New Approaches View all 11 articles

Generalized uncertainty principle and burning stars

H. Moradpour*

A. H. Ziaie*

N. Sadeghnezhad*

A. Ghasemi

Research Institute for Astronomy and Astrophysics of Maragha (RIAAM), University of Maragheh, Maragheh, Iran

Gamow’s theory of the implications of quantum tunneling for star burning has two cornerstones: quantum mechanics and the equipartition theorem. It has been proposed that both of these foundations are affected by the existence of a non-zero minimum length, which usually appears in quantum gravity scenarios and leads to the generalized uncertainty principle (GUP). Mathematically, in the framework of quantum mechanics, the effects of the GUP are considered as perturbation terms. Here, generalizing the de Broglie wavelength relation in the presence of a minimal length, GUP corrections to the Gamow temperature are calculated, and in parallel, an upper bound for the GUP parameter is estimated.

Introduction

In the first step of star burning, its constituents must overcome the Coulomb barrier to participate in nuclear fusion (NF). This means that when the primary gas ingredients have mass m and velocity v, then using the equipartition theorem, one gets

\frac{1}{2} m v^{2} = \frac{3}{2} K_{B} T \geq U_{c} (r_{0}), (1)

where K_B denotes the Boltzmann constant, the subscript c in U_c(r₀) indicates the Coulomb potential, and correspondingly, $U_{c} (r_{0}) = \frac{Z_{i} Z_{j} e^{2}}{r_{0}}$ denotes the maximum of the Coulomb potential between the ith and jth particles located at a distance r₀ from each other (Prialnik, 2000). In this article, Kelvin (K) is the temperature unit. Finally, we reach

T \geq \frac{2 Z_{i} Z_{j} e^{2}}{3 K_{B} r_{0}} ≃ 1 \cdot 1 \times 1 0^{10} \frac{Z_{i} Z_{j}}{r_{0}}, (2)

for the temperature required to overcome the Coulomb barrier. Therefore, NF happens whenever the temperature of the primary gas is comparable to Eq. 2, which clearly shows that, for the heavier nuclei, NF happens at higher temperatures. On the contrary, for the temperature of gas with mass M and radius R, we have (Prialnik, 2000)

T \approx 4 \times 1 0^{6} (\frac{M}{M_{⊙}}) (\frac{R_{⊙}}{R}), (3)

where M_⊙ and R_⊙ are the Sun mass and radius, respectively. Clearly, $T$ and T are far from each other, meaning that NF cannot cause star burning (Prialnik, 2000). Therefore, NF occurs if a process reduces the required temperature (2). In fact, we need a process that decreases Eq. 2 to the values comparable to Eq. 3. Quantum tunneling lets particles pass through the Coulomb barrier, which finally triggers star burning, meaning that quantum tunneling allows NF to occur at temperatures lower than T (Prialnik, 2000). Indeed, if the distance between particles (r₀) becomes of the order of their de Broglie wavelength ( $r_{0} ≃ \frac{ℏ}{p} \equiv λ_{Q}$ where Q implies that we are in the purely quantum mechanical regime), then quantum tunneling happens and simple calculations lead to (Prialnik, 2000)

T \geq \frac{2 Z_{i} Z_{j} e^{2}}{3 K_{B} λ_{Q}} ≃ 9 \cdot 6 \times 1 0^{6} Z_{i}^{2} Z_{j}^{2} (\frac{m}{\frac{1}{2}}) \equiv T, (4)

instead of Eq. 2 for the temperature required to launch star burning. λ_Q can also be obtained by solving ${\frac{p^{2}}{2 m} = U_{c} (r_{0})|}_{r_{0} = λ_{Q}}$ which gives (Prialnik, 2000)

λ_{Q} = \frac{ℏ^{2}}{2 m Z_{i} Z_{j} e^{2}}, (5)

meaning that quantum tunneling provides a platform for NF in stars (Prialnik, 2000). As an example, for hydrogen atoms, one can see that quantum tunneling leads to $T ≃ 9 \cdot 6 \times 1 0^{6} K$ (comparable to (3)) as the Gamow temperature at which NF is underway. Based on the above argument, it is expected that any change in p affects λ_Q and, thus, these results.

It is also useful to mention here that the quantum tunneling theory allows the above process because the tunneling probability is not zero. Indeed, quantum tunneling is also the backbone of Gamow’s theory of the α decay process (Gamow, 1928). Relying on the inversion of the Gamow formula for α decay, which gives the transmission coefficient, a method has also been proposed for studying the inverse problem of Hawking radiation (Völkel et al., 2019).

The backbone of quantum mechanics is the Heisenberg uncertainty principle (HUP),

Δ x Δ p \geq \frac{ℏ}{2}, (6)

where x and p are ordinary canonical coordinates satisfying [x_i, p_j] = iℏδ_ij. It has been proposed that, in quantum gravity scenarios, the HUP is modified such that (Kempf et al., 1995; Kempf, 1996)

Δ X Δ P \geq \frac{ℏ}{2} (1 + \frac{β_{0} ł_{p}^{2}}{ℏ^{2}} {(Δ P)}^{2}), (7)

called the GUP, where l_p denotes the Planck length and β₀ is the dimensionless GUP parameter. X and P are called generalized coordinates, and we work in a framework in which X_i = x_i, and up to the first order, we have $P_{i} = p_{i} (1 + \frac{β_{0} ł_{p}^{2}}{3 ℏ^{2}} p^{2})$ and $[X_{i}, P_{j}] = i ℏ (1 + \frac{β_{0} ł_{p}^{2}}{ℏ^{2}} P^{2}) δ_{i j}$ (Das and Vagenas, 2008; Motlaq and Pedram, 2014). Moreover, the GUP implies that there is a non-zero minimum length ${(Δ X)}_{\min} = \sqrt{β_{0}} ł_{p}$ . Indeed, the existence of a non-zero minimum length also emerges even when the gravitational regime is Newtonian (Mead, 1964), a common result with quantum gravity scenarios (Hossenfelder, 2013). More studies on quantum gravity can be traced to earlier studies (Lake et al., 2019; Lake et al., 2020; Lake, 2021; Lake, 2022). There have been various attempts to estimate the maximum possible upper bound on β₀ (Zhu et al., 2009; Chemissany et al., 2011; Das and Mann, 2011; Sprenger et al., 2011; Pikovski et al., 2012; Husain et al., 2013; Ghosh, 2014; Jalalzadeh et al., 2014; Scardigli and Casadio, 2015; Bosso et al., 2017; Feng et al., 2017; Gecim and Sucu, 2017; Bushev et al., 2019; Luciano and Petruzziello, 2019; Park, 2020; Aghababaei et al., 2021; Feleppa et al., 2021; Mohammadi Sabet et al., 2021), and among them, it seems that the maximum estimation for the upper bound is of the order of 10⁷⁸ (Scardigli and Casadio, 2015). The implications of GUP on stellar evolution (Moradpour et al., 2019; Shababi and Ourabah, 2020) and the thermodynamics of various gases (Chang et al., 2002; Fityo, 2008; Wang et al., 2010; Hossenfelder, 2013; Motlaq and Pedram, 2014; Moradpour et al., 2021) have also been studied.

Indeed, the existence of a minimal length leads to the emergence of the GUP (Hossenfelder, 2013), and it affects thermodynamics (Chang et al., 2002; Fityo, 2008; Wang et al., 2010; Hossenfelder, 2013; Motlaq and Pedram, 2014; Moradpour et al., 2021) and quantum mechanics (Kempf et al., 1995; Kempf, 1996), as P can be expanded as a function of p. This letter deals with the GUP effects on star burning facilitated by quantum tunneling. Loosely speaking, we investigate the effects of a minimal length on $T$ (the Gamow temperature).

GUP corrections to the tunneling temperature

To proceed further and in the presence of the quantum features of gravity, we introduce the generalized de Broglie wavelength as

λ_{GUP} \equiv \frac{ℏ}{P} . (8)

It is obvious that, as β₀ → 0, one obtains P → p and thus λ_GUP → λ_Q, which is the quantum mechanical result. Indeed, up to first order in β₀, we have $λ_{GUP} = λ_{Q} (1 - \frac{β_{0} l_{p}^{2}}{3 λ_{Q}^{2}})$ , and the thermal energy per particle with temperature T is (Motlaq and Pedram, 2014)

〈 K 〉 = 〈 \frac{P^{2}}{2 m} 〉 = \frac{3}{2} K_{B} T - 3 \frac{β_{0} ł_{p}^{2}}{ℏ^{2}} m K_{B}^{2} T^{2} . (9)

Mathematically, one should find the corresponding de Broglie wavelength by solving the following equation:

{\frac{P^{2}}{2 m} = U_{c} (r_{0})|}_{r_{0} = λ_{GUP}} . (10)

Inserting the result into

{\frac{3}{2} K_{B} T - 3 \frac{β_{0} ł_{p}^{2}}{ℏ^{2}} m K_{B}^{2} T^{2} \geq U_{c} (r_{0})|}_{r_{0} = λ_{GUP}}, (11)

one can finally find the GUP corrected version of Eq. 4.

Now, inserting λ_GUP into Eq. 10 and then combining the results with Eq. 11, we find

\begin{matrix} T_{GUP}^{\pm} = \frac{ℏ^{2} (1 \pm \sqrt{1 - 8 β_{0} l_{p}^{2} m K_{B} T / ℏ^{2}})}{4 β_{0} K_{B} l_{p}^{2} m} . \end{matrix} (12)

in which Eq. 4 has been used for simplification. To estimate the magnitude of $l_{p}^{2} m K_{B} T / ℏ^{2}$ , we consider the hydrogen atom for which m ∼ 10^–27 kg. Now, since l_p ∼ 10^–35 m, $K_{B} \sim 1 0^{- 23} \frac{m^{2} k g}{s^{2} K}$ , $ℏ \sim 1 0^{- 34} \frac{m^{2} k g}{s}$ , and $T \sim 1 0^{6} K$ , one easily finds $l_{p}^{2} m K_{B} T / ℏ^{2} \sim 1 0^{- 46}$ . Moreover, because the effects of the GUP in the quantum mechanical regime are small (Hossenfelder, 2013), a reasonable basic assumption could be that $β_{0} l_{p}^{2} m K_{B} T / ℏ^{2} ≪ 1$ . Indeed, if β₀ ≪ 10⁴⁶, then we always have $β_{0} l_{p}^{2} m K_{B} T / ℏ^{2} ≪ 1$ meaning that i) we can Taylor expand our results and ii) 10⁴⁶ is an upper bound for β₀, which is comparable to those found in previous works (Das and Vagenas, 2008; Scardigli and Casadio, 2015; Feng et al., 2017; Aghababaei et al., 2021; Feleppa et al., 2021) summarized in Table 1.

TABLE 1

TABLE 1. Some bounds on the GUP parameter β₀.

Expanding the above solutions (12) and bearing in mind that the true solution should recover $T$ at β = 0, one can easily find that $T_{GUP}^{-}$ is the proper solution leading to

T_{GUP}^{-} = T (1 + 2 β_{0} (\frac{l_{p}^{2} m K_{B} T}{ℏ^{2}})) . (13)

up to first order in β₀. Hence, because it seems that β₀ is positive (Das and Vagenas, 2008; Scardigli and Casadio, 2015; Feng et al., 2017; Aghababaei et al., 2021; Feleppa et al., 2021), one can conclude that $T < T_{GUP}^{-}$ .

Conclusion

Motivated by the GUP proposal and the vital role of the HUP in quantum mechanics and, thus, the quantum tunneling process that facilitates star burning, we studied the effects of the GUP on the Gamow temperature. In order to determine this, the GUP modification to the de Broglie wavelength was addressed, which finally helped us to find the GUP correction to the Gamow temperature and also estimate an upper bound for β₀ (10⁴⁶), which agrees well with those found in previous works (Das and Vagenas, 2008; Scardigli and Casadio, 2015; Feng et al., 2017; Aghababaei et al., 2021; Feleppa et al., 2021).

Finally, based on the obtained results, it may be expected that the GUP also affects the transmission coefficients (Gamow’s formula) (Gamow, 1928; Hossenfelder, 2013; Völkel et al., 2019), meaning that the method of Völkel et al. (2019) will also be affected. This is an interesting topic for future study because Hawking radiation is a fascinating issue in black hole physics (Wald, 2001).

Data availability statement

The original contributions presented in the study are included in the article/Supplementary material. Further inquiries can be directed to the corresponding author.

Author contributions

All authors listed have made a substantial, direct, and intellectual contribution to the work and approved it for publication.

Acknowledgments

The authors would like to appreciate the anonymous referees for their valuable comments.

Conflict of interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

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References

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