Semiregular variable star
Semiregular variable stars are giant or supergiant stars of intermediate and late spectral types, such as M, C, and S, that exhibit brightness variations with noticeable but often irregular periodicity due to radial pulsations in their extended envelopes. These variations typically have periods ranging from 20 days to more than 2000 days and visual amplitudes of several hundredths to several magnitudes, usually 1–2 magnitudes, with light curves that can differ significantly in shape.[1] The General Catalogue of Variable Stars (GCVS) classifies semiregular variables into several subclasses to account for differences in spectral type, regularity of pulsation, and evolutionary status. SRa stars are late-type giants (M, C, S, and their emission-line variants) with persistent periodicity, amplitudes less than 2.5 magnitudes in V, and periods of 35–1200 days; SRb are similar giants but with poorly defined or alternating periodic and irregular changes, periods of 20–2300 days; SRc are late-type supergiants with amplitudes around 1 magnitude and periods from 30 days to several thousand days; SRd encompass F, G, or K giants and supergiants, often with emission lines, amplitudes of 0.1–4 magnitudes, and periods of 30–1100 days; and SRs are short-period (days to a month) red giants likely pulsating in high overtones.[1] These subclasses highlight the diversity within the group, where fundamental-mode pulsations dominate in more regular cases akin to Mira variables, while multi-periodic or chaotic behavior occurs in others due to overlapping pulsation modes or stochastic processes.[2] Notable examples include Betelgeuse (α Orionis), a red supergiant classified as SRc with a primary period of about 400 days and amplitudes up to 1.5 magnitudes, and Antares (α Scorpii), a slow irregular variable (LC) red supergiant in the Hertzsprung-Russell diagram.[3][4] Other prominent semiregular variables are L2 Puppis, an SRa star showing complex light curves indicative of evolutionary transitions, and μ Cephei, a hypergiant with irregular outbursts.[5] Semiregular variables represent a critical phase in the asymptotic giant branch (AGB) evolution of low- to intermediate-mass stars, marking the onset of significant mass loss through stellar winds and providing insights into the dynamical atmospheres of evolved stars. Their pulsations drive dust formation and circumstellar envelopes, influencing galactic chemical enrichment, and while less precise than Miras for distance measurements, they serve as standard candles in nearby galaxies and probes of stellar structure models.[2]Overview
Definition
Semiregular variable stars are giant or supergiant stars of intermediate and late spectral types, including M, C, and S classes, that display periodic light variations which are not strictly regular.[6] These stars exhibit noticeable periodicity in their brightness changes, often interrupted by intervals of semiregular or irregular fluctuations, setting them apart from other variable star classes.[6] The defining characteristic of semiregular variables is their quasi-periodic or multi-periodic behavior, where light curves show appreciable repetition but lack the precise regularity seen in types like Cepheids.[7] This irregularity arises from complex interactions in their atmospheres and envelopes, leading to variations that can include multiple overlapping cycles.[6] Primarily, semiregular variables consist of asymptotic giant branch (AGB) stars or red supergiants, representing evolved, cool luminous phases in stellar evolution.[7] Their pulsations, driven by internal thermal instabilities, are the general cause of these light variations.[6]General Characteristics
Semiregular variable stars exhibit light variations with amplitudes ranging from 0.01 magnitudes to several magnitudes, though commonly 1–2 magnitudes in the V filter.[6] Their periods span from 20 days to over 2000 days, frequently displaying multiple overlapping periods or intervals of irregularity that result in non-repeating light curves suggestive of superimposed pulsation modes.[1][8] These photometric traits distinguish them from more regular pulsators like Mira variables, which have larger amplitudes and stricter periodicity.[2] Spectrally, semiregular variables are predominantly giants or supergiants of late spectral types, including M, C, and S classes, characterized by prominent molecular absorption bands such as titanium oxide (TiO) in M-type giants.[8] Earlier subtypes, like those in F, G, or K classes, may show weaker or occasional TiO features alongside metallic lines.[9] These spectral signatures reflect cool, extended atmospheres conducive to molecule formation. In evolutionary terms, semiregular variables are closely associated with the asymptotic giant branch (AGB) phase of stellar evolution, where stars undergo significant mass loss that forms circumstellar dust envelopes, often detectable through infrared excess or radial velocity variations.[8] Some reside on the red giant branch (RGB) or in post-AGB stages, contributing to their observed irregularity as they transition toward planetary nebula formation.[6]Classification
Subtypes
Semiregular variable stars are classified into subtypes primarily based on their spectral types, pulsation periods, light amplitudes, and the degree of regularity in their light curves, as standardized in the General Catalogue of Variable Stars (GCVS).[10] These subtypes distinguish variations in stability and physical characteristics among giants and supergiants exhibiting semiregular behavior. The SRa subtype consists of late-type giants with spectral classes M, C, or S (or their emission-line variants Me, Ce, Se), featuring persistent single or multiple periodicities, with amplitudes and light-curve shapes that generally vary, periods ranging from 35 to 1200 days and visual amplitudes less than 2.5 magnitudes.[10] In contrast, SRb variables are also late-type giants of similar spectral classes but display poorly defined periods or alternating intervals of periodic and irregular variations, with periods from 20 to 2300 days and possible episodes of near-constancy.[10] SRc subtypes are characterized by late-type supergiants (M, C, S or Me, Ce, Se) with amplitudes around 1 magnitude in the visual band and periods from 30 days to several thousand days.[10] SRd variables encompass giants or supergiants of earlier spectral types F, G, or K (occasionally with emission lines), with periods between 30 and 1100 days and amplitudes ranging from 0.1 to 4 magnitudes in the visual.[10] Additionally, the SRs subtype includes short-period semiregular red giants, often pulsating in high overtones with periods of days to about a month. The SRs subtype was introduced in later updates to the GCVS (Name-Lists 67-77 and vol. V).[10]Relation to Other Variable Stars
Semiregular variable stars share significant similarities with Mira variables, as both classes consist of long-period pulsating red giants and supergiants on the asymptotic giant branch (AGB) of stellar evolution.[8] Unlike Miras, however, semiregulars exhibit smaller photometric amplitudes, typically less than 2.5 magnitudes in the visual band, and their periods are less strictly regular, often showing multi-periodic or quasi-periodic behavior.[10] This distinction arises from the underlying pulsation modes, where Miras predominantly pulsate in the fundamental mode with high regularity, while semiregulars display a mix of radial and non-radial modes leading to more variable light curves.[11] In contrast to irregular variables such as the Lb subtype, semiregulars demonstrate detectable periodicity in their light variations, albeit with some irregularity in amplitude and timing.[10] Lb variables, characterized by slow, non-periodic fluctuations in late-type giants without discernible cycles, often represent insufficiently observed stars that may later reveal semiregular patterns upon extended monitoring.[12] The boundary between these classes is thus somewhat fluid, with many initially classified Lb objects reclassified as semiregular after period analysis confirms underlying pulsations. Semiregular variables of the SRd subtype show overlaps with RV Tauri stars in spectral types, both featuring F to K supergiants with pulsational variability.[14] However, SRd stars differ in their period-amplitude behavior, displaying semiregular pulsations with periods from 30 to 1000 days and amplitudes under 2 magnitudes, whereas RV Tauri stars exhibit characteristic alternating deep and shallow minima on shorter cycles of 30 to 150 days due to binarity and dust effects.[10] This spectral overlap suggests possible evolutionary connections in post-AGB phases, though their light curve morphologies remain distinct.[15] Some semiregular variables exhibit overlaps with symbiotic stars, where the cool giant component undergoes pulsational variability akin to semiregular behavior.[16] In these systems, the primary variability stems from the pulsations of the red giant, with additional photometric changes from accretion onto a hot companion, but the semiregular pulsations dominate the long-term light curve.[17] Such overlaps highlight how pulsational instability in AGB stars can coexist with binary interactions without altering the core classification.[18] Evolutionarily, late-type semiregular variables (SRa, SRb, SRc) serve as an intermediate stage in the AGB evolution of low- to intermediate-mass stars, between earlier red giant branch phases and the more evolved, higher-amplitude Mira variables, reflecting increasing envelope instability and mass loss. SRd variables may relate to different evolutionary stages, potentially post-AGB or in higher-mass progenitors.[8] As AGB stars progress through thermal pulses, semiregular pulsations may transition to the more regular Mira phase.[19] This positioning underscores their role in tracing late-stage stellar evolution.[20]Pulsation Mechanisms
Physical Processes
Semiregular variable stars exhibit variability primarily through radial pulsations in their extended envelopes, akin to those in Mira variables but typically involving higher overtones or multiple modes rather than the fundamental mode alone.[21] These pulsations cause periodic expansions and contractions of the stellar surface, leading to luminosity changes as the radius and temperature vary. In asymptotic giant branch (AGB) stars, which comprise most semiregular variables, the envelopes are convective and loosely bound, facilitating these oscillations with periods ranging from tens to hundreds of days.[22] The driving force behind these pulsations is the kappa mechanism, operating in the ionization zones of helium and hydrogen within the envelope. During compression, rising temperatures in these partial ionization regions increase opacity (κ), trapping heat and causing further expansion; upon cooling, opacity decreases, releasing energy efficiently.[23] This cyclic modulation of radiative transfer creates a net energy gain for the pulsation, sustaining the instability despite the convective nature of AGB envelopes.[24] Multi-periodicity arises from the superposition of the fundamental mode and higher overtones, resulting in the characteristic semi-regular light curves that lack strict periodicity. Recent 3D radiation hydrodynamics simulations reveal that both radial and non-radial modes can be excited, leading to complex interactions. Observations indicate that most semiregular variables display two or more dominant periods, with ratios suggesting excitation of first and higher overtones rather than solely fundamental and first-overtone combinations. This mode interference produces irregular but quasi-periodic variations, as the amplitudes and phases of individual modes evolve over time. Additionally, stochastic processes and chaotic dynamics can contribute to the observed irregularity, particularly in less stable pulsators, as recent models show a transition from stochastic driving in smaller-amplitude variables to self-excited pulsations in semiregulars.[25] A subset of semiregular variables also exhibit long secondary periods (LSPs), approximately 10 times longer than the primary pulsation period, whose origins remain debated. Possible explanations include binary motion, where a companion induces radial velocity variations and circumstellar obscuration, or dynamical processes in the stellar envelope, such as radial pulsations in the outer layers or non-radial gravity modes.[26][27] Pulsations in semiregular variables enhance mass loss by levitating the envelope and enabling dust-driven winds, where radiation pressure on newly formed dust grains accelerates outflows. This process becomes prominent when pulsation periods exceed about 60 days, increasing mass-loss rates by factors of up to 10 and producing observable infrared excesses from reprocessed stellar light by circumstellar dust. In pulsation theory, the period P approximates the dynamical timescale, scaling as P \propto R / c_s, where R is the stellar radius and c_s is the sound speed (assumed roughly constant). For AGB stars with similar effective temperatures, luminosity L \propto R^2 T_{\rm eff}^4 \approx R^2, so R \propto \sqrt{L} and thus P \propto \sqrt{L}. This yields the approximate period-luminosity relation P \propto L^{0.5}, modulated by envelope density variations.[23][28]Periods and Amplitudes
Semiregular variable stars exhibit primary pulsation periods typically ranging from 20 to over 2000 days, though most fall between 30 and 1200 days depending on subtype.[10] These stars often display multi-periodic behavior, with a dominant short primary period accompanied by a longer secondary period that can be approximately ten times the primary, contributing to their semi-regular variability.[29] Such multi-periodicity arises from the excitation of multiple pulsation modes, complicating the identification of individual cycles.[30] Amplitude variations in these stars are generally small, ranging from several hundredths of a magnitude up to 2.5 magnitudes for the more stable SRa subtype, while SRd variables can reach up to 4 magnitudes.[10] Factors influencing these variations include interference between pulsation modes, leading to episodes of reduced or enhanced amplitude over time.[30] Light curves typically show quasi-sinusoidal shapes for more regular pulsations or irregular, sawtooth-like forms during unstable phases, which are analyzed using Fourier decomposition to extract dominant periods and harmonics.[30] The inherent irregularity of semiregular variables necessitates long-term photometric monitoring to resolve periods accurately, as short-term observations often fail to capture multi-periodic trends or amplitude drifts. Surveys such as the All Sky Automated Survey (ASAS) and Gaia provide essential datasets spanning years to decades for this purpose.[31][32] Longer periods in these stars correlate with increased luminosity and stellar radius, as described by the pulsation period-mean density relation, where the approximate envelope pulsation timescale is given byP \approx 2\pi \sqrt{\frac{R^3}{GM}},
with R as the radius, G the gravitational constant, and M the mass, linking observable variability to underlying stellar structure.[33]