2. Ubiquity of circumbinary planets

In the currently available sample of two dozens of the observed stellar binaries hosting circumbinary planets, about a half have periods less than several hours, and about a half have periods that are greater than 5 d (see, e.g., exoplanet.eu). There is a dearth of CBP-hosting binaries with intermediate periods. Indeed, according to (Slawson et al. Reference Slawson, Prša, Welsh, Orosz, Rucker, Batalha, Doyle, Engle, Conroy, Coughlin, Gregg, Fetherolf, Short, Windmiller, Fabrycky, Howell, Jenkins, Uddin, Mullally, Seader, Thompson, Sanderfer, Borucki and Koch2011, fig. 8), in a sample of two thousands of eclipsing binaries in the Kepler data, more than a thousand have periods less than 7 d, but practically none are known to possess planets.

A number of observational biases are active, but the actual dearth of CBP-hosting binaries with $P \lesssim 5\, {\rm d}$ seems to be statistically significant (Armstrong et al. Reference Armstrong, Osborn, Brown, Faedi, Gómez Maqueo Chew, Martin, Pollacco and Udry2014; Martin and Triaud Reference Martin and Triaud2014). Fleming et al. (Reference Fleming, Barnes, Graham, Luger and Quinn2018) explained the dearth by eventual entrance of CBPs in the circumbinary chaotic zone, in the course of the long-term planet-binary co-evolution. In the tidal scenario of Fleming et al. (Reference Fleming, Barnes, Graham, Luger and Quinn2018), the circumbinary chaotic zone slowly broadens (because the binary's orbit increases in size, due to the tidal transfer of the angular momentum from the stellar rotation), while the planetary orbit size stays constant. This mechanism of entrance in the chaotic zone is different from that proposed in Shevchenko (Reference Shevchenko2018), where the planetary orbit tidally decays in size, while the chaotic zone size stays constant.

It should be underlined that (1) the observed dearth concerns Neptune-like and Jupiter-like giant planets; observational statistics on terrestrial CBPs, whose sizes are much smaller, is lacking, because such small planets are simply hard to discover; (2) the dearth has an intermediate character: as already mentioned above, CBPs of very close (with periods less than several hours) binaries do exist, although these hosting binaries typically contain evolved stars.

Generally, the close Solar-type binaries with periods less than 10 d are believed to be a product of some long-term dissipative evolution, most likely a tidal friction, which is triggered in hierarchical triples by the Lidov–Kozai oscillations (Armstrong et al. Reference Armstrong, Osborn, Brown, Faedi, Gómez Maqueo Chew, Martin, Pollacco and Udry2014; Martin et al. Reference Martin, Mazeh and Fabrycky2015; Muñoz and Lai Reference Muñoz and Lai2015; Hamers et al. Reference Hamers, Perets and Portegies Zwart2016). On the other hand, the existing correlation between companions’ masses and the resemblance between the close-binary fractions for the pre-main-sequence stars and for the main-sequence field stars show that the evolution to the close state is fast, taking $\lesssim 5\, {\rm Myr}$, most likely due to the dissipation in primordial gas (Moe and Kratter Reference Moe and Kratter2018). Therefore, the potential existence of CBP-hosting main-sequence pre-merger stellar binaries is quite plausible; in any case, it is not ruled out.

3. Biopolymer chain reactions

4. Contact binaries

We consider stellar eclipses in contact binaries as drivers of temperature forcing on CBPs. For the PCR-like reaction be triggered, the forcing frequency should be large enough. Among the ordinary stellar binaries, the tightest ones are contact binaries, mostly represented by W UMa-type stars. For them, the binary mass is ~2 Solar masses, and the binary size (the distance between the companions’ mass centres) is ~2 Solar radii. Generally, W UMa-type stars belong to F, G and K spectral classes, and their ages range from ~5 to ~12 Gyr; see Stȩpień and Gazeas (Reference Stȩpień and Gazeas2012) and references therein. They are rather ubiquitous; thousands of them are catalogued, and they populate the Solar neighbourhood in ratio of ~2 contact binaries for a thousand single stars (Rucinski Reference Rucinski2006). They are believed to be formed from initially detached binaries, as the size of the latter slowly but inevitably diminishes due to the stellar winds and mutual tides, which transfer the angular momentum away (Stȩpień and Gazeas Reference Stȩpień and Gazeas2012). A final merger, manifesting the birth of a rapidly rotating post-binary single, is the natural outcome of this slow evolution.

Let F _min and F _max be the observed minimum and maximum stellar fluxes during the eclipse cycle of a stellar binary (for an observer on a CBP in an orbit coplanar with the binary's orbit; this coplanarity is typical for the observed CBPs). The corresponding stellar magnitude variation is Δm = 2.5log₁₀(F _max/F _min). Therefore, if the ratio of fluxes is F _max/F _min ≈ 2, then the lightcurve relative amplitude Δm ≈ 0.75. This value is rather typical for the observed lightcurves of W UMa-type stars, see Terrell et al. (Reference Terrell, Gross and Cooney2012). This reflects the fact that the companions in the contact binaries have similar sizes, and, besides, the orbital planes of many such binaries are rather moderately inclined to the line of sight, due to selection biases.

Now, let F _min and F _max be the minimum and maximum stellar fluxes at the surface of a CBP during the eclipse cycle. In a simplest model setting, the temperature variation is determined by the Stefan–Boltzmann law:

(1)$${\Delta T\over T_{\rm min}} = \left({\Delta F\over F_{\rm min}} + 1 \right)^{1/4} - 1 \comma\; $$

where ΔT = T _max − T _min, ΔF = F _max − F _min. For ΔF/F _min = 1 one has, then, ΔT/T _min = 0.189. Therefore, for T _min ≈ 300 K (i.e., for a planet in the HZ) one has ΔT ≈ 57^°.

More specifically, for Δm = 0.7–0.9, typical for W UMa-type stars (Terrell et al. Reference Terrell, Gross and Cooney2012), one has ΔF _max/F _min = 0.91–1.29 and, therefore, $\Delta T \approx 50\hbox {-\!-}70^\circ$. For maintaining the authentic PCR, similar temperature amplitudes are perfectly suited; see Mullis et al. (Reference Mullis, Faloona, Scharf, Saiki, Horn and Erlich1986); Lathe (Reference Lathe2004, Reference Lathe2005).

In case of a twin (equal-mass equal-radius) binary the lightcurve period is effectively two times less than the binary's orbital period. The heating/cooling period at the planetary surface is therefore equal to one half of the binary's period. For example, let the orbital period be 8 h = 0.33 d (as in case of the W UMa prototype), then the lightcurve (eclipse) period is 4 h, and the heating/cooling period is 4 h.

The binary orbital period P is given by the Keplerian equation

(2)$$P^2 = {4 \pi^2 a^3\over {{\cal G}} \lpar m_1 + m_2\rpar } \comma\; $$

where ${{\cal G}}$ is the gravitational constant, m ₁ ≥ m ₂ are the masses of the companions, a is the binary size (the distance between the companions’ mass centres). Let r ₁ ≥ r ₂ be the radii of the companions, and α = r ₂/r ₁. Then, for a contact binary whose companions have equal mean densities ρ, one has

(3)$$P^2 = {3 \pi\over {{\cal G}} \rho} \cdot {\lpar 1 + \alpha\rpar ^3\over \lpar 1 + \alpha^3\rpar } \comma\; $$

and, for a twin contact binary (α = 1),

(4)$$P = 2 \left({3 \pi\over {{\cal G}} \rho} \right)^{1/2} .$$

Using equation (4) and data for masses and radii for red dwarfs as given in (Kaltenegger and Traub Reference Kaltenegger and Traub2009, table 1), one obtains the orbital periods equal to ≈200 and ≈27 min for twin contact binaries of spectral classes M0 and M9, respectively. Therefore, the heating/cooling periods are ≈100 and ≈14 min, respectively. For maintaining the authentic PCR (Lathe Reference Lathe2004, Reference Lathe2005; Mullis et al. Reference Mullis, Faloona, Scharf, Saiki, Horn and Erlich1986) such periods are perfectly suited.

However, in the entire sample of the known to date thousands of contact binaries, the shortest measured orbital period is ≈0.22 d = 5.28 h (Stȩpień Reference Stȩpień2006), corresponding to the heating/cooling period ≈2.6 h ≈160 min. The shortest orbital period belongs to CC Com. The absence of observed contact binaries with shorter periods is generally attributed to the slowness of M-dwarf binary inspiralling; it is therefore believed that M-dwarf contact binaries have not yet formed (Stȩpień Reference Stȩpień2006). Comparing the age of the Universe and the time needed to reach the Roche lobe overflow at various stellar masses, one may estimate the expected total (for the two companions in sum) lower mass limit for the observed contact binaries to be ≈1.0–1.2 in Solar units (Stȩpień Reference Stȩpień2006), in accord with the mentioned lower period limit ≈0.22 d. If the given explanation of the contact binary period distribution cut-off is valid, then the massive biopolymer chain reaction scenario may come into play only in a far (Gigayears ahead) future.

5. Biomass inflation

PCR is hyper-efficient to inflate biomass and, therefore, to provide better storage of evolved bioinformation. In a DNA molecule, there are 2400 million atoms in a single strand of a chromosome; thus, its mass is ≈ 7 · 10⁻¹⁴ g. On the other hand, the volume of the World Ocean on the Earth is ≈ 1.3 · 10²⁴ cm³; and its mass is ≈ 1.3 · 10²⁴ g. Therefore, the time needed to produce, starting from one DNA molecule, a World Ocean mass (as an example) of copied molecules (provided that the precursor material is enough) is equal to only ≈ log₂ 10³⁷ ~100 eclipse cycles.

In case of Solar-like G-dwarf twin contact binaries, the hundred cycles take ~400 h ~2 weeks; and, in case of M-dwarf twin contact binaries, the hundred cycles take only ~1 d. Thus, the biomass inflation time is negligible in comparison with cosmogonical timescales; therefore, possible activity of host stars does not inflict the process.

There exists an obstacle: planets rotate, and, therefore, there may exist periodic time intervals when the rapid heating/cooling cycle is inactive, and this may break the chain reaction. Note, however, that the day-side polar region would be mostly unaffected, if the planet's rotation axis is inclined. Moreover, in case of red-dwarf hosting binaries, the planets inside the HZ are expected to be tidally locked (Barnes Reference Barnes2017), i.e., reside in synchronous spin-orbit resonance. This would permit the chain reactions on the planet's day side to be continuous. Note that in case of late-type M dwarfs there may be even no need for the planet to be tidally locked, because the amplification process saturates in less than a day.

Apart from PCR-type reactions, the TCR may also be active, due to what in the Earth case is called the lunitidal interval – the time lag of the tide maximum after the geometrically closest passage of the Moon. The lunitidal interval on Earth can be as large as ~2 h; generally, it may take a whole spectrum of values, depending on many local and global geophysical factors (Grant Gross Reference Grant Gross1971). Therefore, at least at some localities on a planetary surface, PCR and TCR may well act in concertFootnote ⁴.

Note that, inside the HZ, the entire spectrum of temperatures, from zero to ≈ 100^°C, allowing for the water liquid state, can be maintained, depending on the planetary orbital radius. Besides, the broad range of temperatures can be maintained on any planet inside the HZ. For example, for a tidally locked planetFootnote ⁵, the temperature would be maximum in the planetary surface locations where the host star is in zenith, and would sharply decrease towards the day-night line. Therefore, suitable locations for maintaining biopolymer chain reactions seem to be always potentially present, both in the orbital space inside the HZ and in the planetary surface areas.

During the W UMa stage, the possible enormous production of biomaterial on CBPs in HZs would inevitably force the biomaterial to penetrate throughout the planetary surfaces and close-to-surface inner volumes, thus providing safer shelters allowing for the survival of the bioinformation during any violent space weather storms associated with the host binary star merger. As in any extinction event, the more material is stored beforehand (especially in safe shelters), the more material is expected to survive.

6. Post-binary potential biosystem reboot

SX Phe-type stars are A–F type main-sequence stars that pulsate with short periods (down to 0.03 d) and large amplitudes (up to 0.8m); see Eggen and Iben (Reference Eggen and Iben2009); Nemec et al. (Reference Nemec, Balona, Murphy, Kinemuchi and Jeon2017); McNamara (Reference McNamara2011). These properties provide almost the same, as in the W UMa-type stars case, conditions for maintaining the BCR on their planets in habitability zones. In fact, the shortness and general similarity of periods of the contact-binary rotations and the post-binary pulsations seem to be not at all accidental: indeed, the fundamental mode pulsations of a post-binary star have the period $P \sim \lpar {{\cal G}} \rho \rpar ^{-1/2}$, which coincides with the period given by equation (4) for the pre-merging contact-binary rotation.

Thus, the post-binary stars pulsate with periods and amplitudes well suited for maintaining the BCR. The SX Phe-type stars are presumably post-binaries, i.e., products of stellar mergers. Therefore, the ‘W UMa–SX Phe’ metamorphosis (from a contact binary to a post-binary, via the merger) may potentially provide a potential biosystem reboot on planets in these systems.

Note that after the host binary merger, the excessive angular momentum is transferred away by a circumstellar excretion disk newly formed of ex-stellar material. New young planets may form in such disks (Melis et al. Reference Melis, Gielen, Chen, Rhee, Song and Zuckerman2011; Martin et al. Reference Martin, Spruit and Tata2011; Stȩpień and Kiraga Reference Stȩpień and Kiraga2013). One may speculate that, before the merger, by means of BCR the bioinformation is massively stored to provide a post-merger bio-evolution revival in the old or a newly formed planetary system. After the merger, the survived bioinformation may serve as a basis for a further bio-evolution under a more massive and quiet star – a post-binary single. Contact-binary stars and post-binary single stars (presumably, red, yellow and blue stragglers) may therefore be of especial observational interest as potential hosts of biomarked planets.

The stellar activity, especially the pre-merger one in W UMa-type systems may hinder the detection of biosignatures; therefore, SX Phe-type systems can be chosen as observational targets in this respect first of all.

Generally, in comparison with W UMa-type systems, SX Phe-type ones are expected to possess more quiescent space weather environmental conditions, maybe calm enough to allow for a prokaryotic biosphere similar to that of the early Earth. An evolved biosphere, resembling that of the present-day Earth, may be expected Gigayears later on.

The bio-evolution should include compartmentalization, with self-replicating biopolymers being then contained within protocells. Hypothetically, this step may be not favoured during the W UMa stage, especially for M-dwarf binary systems, due to the potentially active pre-merger behaviour of the stars. However, during the subsequent SX Phe stage, the host star is expected to be calmer, and the bio-evolution may proceed further on.

To author's knowledge, apart from W UMa-type and SX Phe-type stars, no other type of stellar objects may provide suitable periodic variation in heating/cooling radiation fluxes and, therefore, be efficient for maintaining the BCR on planets.