Fact-checked by Grok 2 weeks ago

Behavioral ecology

Behavioral ecology is the of the evolutionary basis for animal behavior, focusing on how ecological pressures shape adaptive responses to maximize survival and . This discipline examines behaviors such as , , , and social interactions through a that integrates and ecology, emphasizing cost-benefit analyses where behaviors persist if their fitness benefits outweigh environmental costs like predation risk or energy expenditure. The field emerged in the 1970s in the from the traditions of , particularly influenced by for analyzing —proximate causes, , adaptive value, and phylogeny—which provided a framework for linking mechanism to . It gained disciplinary coherence by incorporating mathematical models from and to predict adaptive behaviors in specific ecological contexts, distinguishing itself from broader by prioritizing ecological realism over general social . A pivotal milestone was the 1978 publication of Behavioural Ecology: An Evolutionary Approach, edited by J.R. Krebs and N.B. Davies, which synthesized these ideas and established the field as a theoretically driven focused on consequences of . Key concepts in behavioral ecology include , which models how animals select resources to balance energy intake against search and handling costs; kin selection, explained by Hamilton's rule (rB > C, where r is genetic relatedness, B is the benefit to the recipient, and C is the cost to the actor), accounting for altruistic behaviors that enhance ; and , which drives traits and behaviors for mate attraction or competition, often leading to . These principles are tested through field observations, experiments, and comparative analyses across , revealing how behaviors adapt to diverse environments from solitary in insects to cooperative breeding in birds like meerkats. Modern applications extend to , predicting responses to change, and , exploring evolutionary roots of human .

Foundations and Key Concepts

Definition and Scope

Behavioral ecology is the study of the evolutionary basis for animal , focusing on how ecological pressures shape adaptive traits that enhance through . It integrates principles from , , and to explain behaviors such as , anti-predator responses, and social interactions as solutions to environmental challenges. Unlike proximate analyses that examine mechanistic causes like or development, behavioral ecology prioritizes ultimate causation, investigating why behaviors evolve to maximize in specific contexts. The scope of behavioral ecology spans behaviors at , , and levels, encompassing diverse taxa including , , and mammals. For instance, it explores how strategies in like the optimize energy intake amid variable food resources, or how insect social behaviors in facilitate colony-level resource defense. At broader scales, it examines influenced by behavioral interactions, such as in mammalian communities, and community-wide effects like interspecies signaling in mixed-species flocks. This multilevel approach underscores how behaviors mediate ecological processes, from to species coexistence. Interdisciplinary tools form the backbone of behavioral ecology, including to model trait inheritance, to predict conflict resolutions, and to assess decision-making under constraints. Evolutionarily stable strategies provide a framework for understanding persistent behavioral equilibria. In contemporary research, the field has expanded to include behavioral plasticity—the capacity for flexible responses to environmental variability—and its implications for amid global changes. For example, studies highlight how plasticity in patterns helps cope with climate-induced shifts in resource availability. Applications to conservation increasingly address how disrupts behavioral adaptations, such as altered routes in fragmented landscapes that elevate energy costs and reduce .

Historical Development

Behavioral ecology traces its early roots to the fields of and in the mid-20th century. Ethologists such as and Niko Tinbergen laid foundational work by emphasizing the biological mechanisms and adaptive significance of animal behavior, with Tinbergen's 1963 framework of four questions—causation, ontogeny, function, and evolution—providing a structured approach to studying behaviors that influenced the field's shift toward evolutionary explanations. In , David Lack's 1947 analysis of bird clutch sizes demonstrated how reproductive behaviors evolve to maximize fitness under environmental constraints, marking an early integration of ecological pressures with behavioral adaptation. The field coalesced in the 1960s and 1970s through contributions from key figures including Robert Hinde, who bridged and , Niko Tinbergen, and John Crook, whose research on and social organization highlighted ecological influences on group living. A pivotal milestone was the 1975 publication of Edward O. Wilson's Sociobiology: The New Synthesis, which synthesized evolutionary theory with social behaviors across taxa and spurred the application of concepts introduced by in the 1960s to explain and . The field's formal establishment came with John R. Krebs and Nicholas B. Davies's 1978 book Behavioural Ecology: An Evolutionary Approach, which emphasized adaptive value and predictive modeling of behaviors in ecological contexts. In the 1980s, behavioral ecology advanced through the integration of , pioneered by John Maynard Smith's 1982 book Evolution and the Theory of Games, which modeled behavioral strategies as evolutionary equilibria to predict outcomes in conflicts like resource competition. This period marked a broader shift from descriptive to quantitative, predictive evolutionary models. The founding of the Behavioral Ecology journal in 1990 by the International Society for Behavioral Ecology further solidified the discipline's institutional presence. Since the 2000s, the field has incorporated genomic tools to dissect , with post-2010 applications of CRISPR-Cas9 enabling targeted edits to study behavioral traits such as in model . Recent emphases include influences, such as behavioral responses to and alteration, as explored in frameworks that link contaminants to disrupted and patterns.

Evolutionarily Stable Strategies

Evolutionarily stable strategies (ESS) represent a cornerstone of behavioral ecology, providing a game-theoretic framework to predict behavioral outcomes that resist invasion by alternative strategies under . Introduced by and George Price, an ESS is defined as a strategy that, if adopted by the majority of a , cannot be invaded by a rare alternative mutant strategy because the mutant achieves lower . This concept shifts focus from individual optimization to population-level stability, emphasizing where the fitness of a strategy depends on its prevalence in the population. The mathematical foundation of an ESS relies on comparing expected fitness payoffs, denoted as E(X, Y), where X is the strategy of a focal individual and Y is the strategy of opponents in the population. For an incumbent strategy I to be an ESS against an alternative strategy A, it must satisfy: either E(I, I) > E(A, I), meaning residents outperform invaders when rare, or if E(I, I) = E(A, I), then E(I, A) > E(A, A), ensuring that in a mixed encounter, the incumbent has higher fitness. This condition formalizes resistance to invasion and underpins analyses of conflict and cooperation in behavioral interactions. A classic application is the Hawk-Dove game, modeling contests over resources where "Hawk" employs aggressive escalation and "Dove" uses non-aggressive displays. In this symmetric game, pure Hawk or pure Dove strategies are unstable, but a mixed ESS emerges where individuals adopt Hawk with probability p = V/C (resource value V over contest cost C), stabilizing aggression at a level where further increases reduce population fitness. Extensions to mixed strategies accommodate polymorphism, as in frequency-dependent scenarios where strategy success varies with relative abundance, allowing ESS to predict diverse behavioral repertoires without genetic dimorphism. ESS models assume infinite populations with perfect information and fixed strategies, simplifying evolutionary dynamics but overlooking real-world complexities. Critiques highlight that finite populations introduce , potentially destabilizing ESS predictions, as demonstrated in simulations showing deviations from ESS equilibria in small groups post-1990s. Additionally, environmental stochasticity and learning can alter strategy expression, challenging the static nature of ESS by introducing adaptive not captured in basic formulations. Empirical support for appears in alternative reproductive tactics, such as in bluegill sunfish (Lepomis macrochirus), where males adopt either parental nesting (cuckold-vulnerable) or sneaking (low-investment) tactics. maintains a stable mix, with sneaker fitness declining as their proportion rises, aligning with ESS predictions for polymorphism in behaviors.

Resource Competition and Foraging

Foraging Behaviors

Foraging behaviors in behavioral ecology encompass the strategies animals employ to acquire food resources in ways that maximize , particularly net energy intake, by balancing the benefits of energy gained against the costs of searching, pursuing, and handling prey. (OFT) posits that foragers evolve to make decisions that optimize these trade-offs in unpredictable environments, where food patches vary in profitability and distribution. A key framework within OFT is the central place foraging model, which applies to animals that return to a fixed location, such as a nest or den, after each foraging bout; here, foragers must consider travel time and load size to maximize net energy returns, as larger loads increase handling time but reduce trip frequency. This model predicts that central place foragers will select prey or patches closer to the central place or those allowing efficient loading, thereby minimizing overall energy expenditure. Central to OFT are models like the (MVT), which addresses how long a forager should remain in a depleting patch before moving to another. According to the MVT, a forager should leave a patch when the instantaneous rate of intake equals the average rate of intake across the environment, including travel time between patches. This optimal patch t^* is determined by solving : \frac{\int_0^{t^*} r(t) \, dt}{t^* + T} = R where r(t) is the instantaneous resource intake rate in the patch at time t, T is the travel time between patches, and R is the average environmental intake rate (overall resources divided by total time, including travel). The MVT has been empirically supported in various taxa, demonstrating that foragers adjust patch use based on depletion and environmental quality to achieve higher net returns. Behavioral adaptations under OFT include variations in diet breadth, where specialists focus on high-profitability prey when abundant, while generalists expand to lower-ranked items during to maintain intake rates. Risk-sensitive foraging further refines these decisions, particularly for animals near energy thresholds; when facing , foragers prefer variable patches with potential high rewards over consistent low ones to maximize survival probability, as variance can provide the surplus needed to avoid deficits. For instance, experiments with yellow-eyed juncos showed that birds in energy-short conditions shifted to risk-prone options, preferring variable seed rewards that offered a chance for higher gains. Empirical studies illustrate these principles across species. In bumblebees, flower choice follows OFT predictions, with foragers moving between inflorescences to maximize nectar intake rates by prioritizing closer, richer patches and minimizing revisits, aligning with MVT departure rules. Among human hunter-gatherers, such as the Ache of , foraging decisions reflect central place constraints and profitability rankings, where hunters select game based on return rates adjusted for search and handling costs, often prioritizing higher-ranked prey near camp. Predation introduces additional trade-offs, compelling foragers to allocate time to vigilance at the expense of intake; for example, small mammals reduce in open areas under high predator threat, balancing energy needs against mortality , as documented in reviews of antipredator behaviors. These examples highlight how foraging efficiency drives evolutionary stability in resource use.

Territoriality and Resource Defense

Territoriality refers to the behavior in which animals defend an area against intruders to gain exclusive access to resources such as , , or mates, thereby reducing and enhancing benefits. This defense provides advantages like predictable resource availability and minimized interference, but it requires ongoing investment in vigilance and confrontation. The economic defensibility model, proposed by J.L. Brown in 1964, posits that territoriality evolves when the benefits of exclusive use outweigh the costs of defense, with factors like density, , and intruder pressure determining viability. In this framework, territories form around patches where value justifies energetic or risky expenditures on maintenance, such as in where clumped food sources promote denser territorial spacing. Animals employ various tactics to establish and maintain , including patrolling boundaries to detect intruders and advertising ownership through displays like vocalizations. For instance, male often use songs to signal territory occupancy and deter rivals without physical contact, as seen in banded wrens where song repertoires effectively reduce intrusions. If advertisement fails, contests may escalate to chases or fights, with outcomes influenced by asymmetries such as the prior residency effect, where established owners hold an advantage due to familiarity with the area or motivation to defend. Defending a involves evolutionary trade-offs, balancing gains in resource monopoly against costs like energy expenditure, time lost to , and injury risk from conflicts. In pied wagtails (Motacilla alba), territory spacing adjusts to availability along riverbanks, with individuals optimizing defense effort where density supports the net benefit, leading to closer territories in richer patches. This hawk-dove dynamic, analyzed through evolutionarily stable strategies, illustrates how aggressive "hawk" tactics prevail in high-value disputes while "dove" avoidance stabilizes low-stakes interactions. Empirical studies highlight territoriality across taxa; in insects, male butterflies like the speckled wood (Pararge aegeria) defend sunlit perch sites as leks to intercept females, with residents achieving higher mating success through persistent aerial contests. Among mammals, (Suricata suricatta) groups maintain large territories via collective scent-marking and patrols, where sentinel behavior—though primarily antipredator—indirectly supports defense by enabling early detection of neighboring intruders during boundary disputes. Contemporary research reveals how human-induced changes affect territoriality; and often result in smaller territories, as observed in house wrens (Troglodytes aedon) where high urban density compresses ranges due to resource scarcity and increased in remnant patches.

Ideal Free Distribution

The ideal free distribution (IFD) model predicts how animals for resources distributed across patches will distribute themselves to equalize per capita returns across patches, thereby maximizing individual . Developed by Fretwell and Lucas in 1970, the model assumes that foragers possess perfect knowledge of patch profitability ("ideal") and can relocate without cost or interference from others ("free"), resulting in a stable equilibrium where no individual benefits from switching patches. This framework builds on behaviors by extending individual resource acquisition decisions to population-level spatial patterns. The mathematical foundation of the IFD relies on density-dependent resource intake rates. For a simple case of two patches with differing resource input rates R_1 > R_2, the equilibrium distribution of forager densities D_1 and D_2 satisfies D_1 / D_2 = R_1 / R_2, such that the intake rate R_i / D_i is equal in both patches. This input matching rule implies that more profitable patches attract proportionally more foragers until equalizes gains, with intake declining with density in multi-patch scenarios. Empirical tests of the IFD have supported its predictions in controlled settings, particularly through input matching observations. A classic example involves cichlid fish (Aequidens curviceps) on patchily distributed prey, where fish distributed themselves proportionally to food input rates across two tanks, achieving near-equal rates after initial adjustments. Field studies with stream minnows (Rhinichthys atratulus) have similarly shown distributions approximating IFD predictions when accounting for travel costs between patches, though exact matching varies with environmental constraints. Deviations from the classic IFD often arise due to violations of its assumptions, such as interference competition or imperfect information. Interference, including where foragers steal resources from others, leads to uneven as dominant individuals monopolize high-quality patches, reducing overall matching to inputs. Preemptive models address arrival order effects, predicting that early in better patches gain priority access, causing later arrivals to undermatch in distribution compared to simultaneous scenarios. The IFD has practical applications in , such as predicting animal distributions in restored habitats to optimize resource placement. It informs efforts to model patterns across variable food patches in changing environments, with implications for .

Mating Behaviors and Sexual Selection

Mating Systems

Mating systems in behavioral ecology refer to the patterns of mate acquisition and association, classified primarily by the number of partners per individual and the duration of pair bonds. Common systems include , where individuals have multiple partners without lasting bonds; , involving exclusive pair bonds between one male and one female; , where one male mates with multiple females; , where one female mates with multiple males; and , where both sexes have multiple partners. These classifications are shaped by ecological pressures such as resource distribution and asymmetries, which influence the evolution of mating strategies under . Ecological drivers often determine system prevalence; for instance, clumped resources favor by allowing males to defend high-quality territories that attract multiple females, as seen in elephant seals (Mirounga spp.), where dominant males form harems of up to 200 females through intense male-male competition in the absence of . In contrast, uniform resource distribution promotes , particularly in species requiring biparental care, such as approximately 90% of bird species that form socially monogamous pairs to ensure offspring survival. Polyandry arises in cases of sex , where males provide greater , limiting female mating opportunities; the Gulf pipefish (Syngnathus scovelli) exemplifies this, with females competing for access to males' brood pouches, resulting in extreme and female-biased . In systems without male parental care, alternative tactics like and sneaker males emerge, where subordinate males exploit dominant pairings to gain fertilizations. For example, in (Oncorhynchus tshawytscha), "jack" sneaker males rapidly inseminate eggs during spawning bouts dominated by larger "hooknose" males, achieving competitive sperm success without territorial defense. The , proposed by Orians in 1969, explains female willingness to join already-mated males if the resources on their territories exceed the benefits of solitary breeding, predicting higher in species with renewable, defensible food supplies. Genetic studies since the have revealed that many socially monogamous systems involve extra-pair copulations, challenging strict classifications; in biparental bird species, an average of 19% of offspring result from extra-pair paternity, with rates often ranging 20-30% across populations. These findings highlight how ecological factors, such as operational sex ratios and predation risks, can drive cryptic even in pair-bonded systems.

Mechanisms of Sexual Selection

Sexual selection operates through two primary mechanisms: intrasexual selection, where individuals of one sex compete with each other for access to mates, and intersexual selection, where members of one sex choose mates based on traits exhibited by the other sex. Intrasexual selection often favors traits that enhance competitive ability, such as weaponry or physiological adaptations that improve success in rival interactions. Intersexual selection, conversely, promotes traits that signal attractiveness or genetic quality to potential mates, leading to the evolution of elaborate displays. Intrasexual selection manifests in direct male-male combat, where physical structures like antlers in deer (Cervidae) serve as weapons to establish dominance and secure mating opportunities. For instance, in (Cervus elaphus), larger antlers correlate with higher success in agonistic encounters during the rutting season, allowing dominant males to monopolize harems. Another form is , arising when females mate with multiple males, prompting adaptations like prolonged copulation in to displace rival sperm or protect one's own. In the (Ephestia kuehniella), males extend copulation duration to increase their paternity share by physically blocking subsequent inseminations. Intersexual selection typically involves female choice for male traits that indicate underlying viability or genetic benefits, driving the evolution of conspicuous ornaments. A key process here is runaway selection, proposed by , in which an initially arbitrary female preference for a male trait becomes genetically linked to the trait itself, leading to mutual exaggeration until balanced by . This mechanism explains the rapid divergence of sexually selected traits across populations without direct survival costs. Complementing this is the , articulated by Amotz Zahavi, which posits that reliable signals of quality must be costly to produce or maintain, ensuring honesty because only high-quality individuals can bear the burden without compromising survival. For example, elaborate in birds may signal health only if its development imposes significant energetic or immunological demands. Empirical support for intersexual selection comes from manipulation experiments, such as those on long-tailed widowbirds (Euplectes progne), where artificially elongating tail feathers by 20-40% increased their mating success by attracting more s to territories, demonstrating that exaggerated traits directly influence beyond limits. Modern critiques highlight the necessity of genetic correlations between preferences and traits for processes to initiate and sustain, as weak or absent linkages may prevent escalation. Additionally, sensory drive—where environmental factors alter signal efficacy—complicates these mechanisms; for instance, urban noise since the early 2000s has shifted bird song frequencies in species like great tits (Parus major), potentially disrupting preferences for low-frequency calls that signal dominance, thus altering dynamics in novel habitats.

Mate Choice Processes

Mate choice processes in behavioral ecology refer to the mechanisms by which individuals, typically females, evaluate and select partners based on traits that signal direct or indirect benefits. These processes are shaped by evolutionary pressures, where choosers assess potential mates through sensory cues, behavioral displays, and environmental contexts to maximize . Key criteria include resources provided by mates, genetic quality indicators, and pre-existing sensory preferences, often balanced against the costs of evaluation. Resource-based mate choice emphasizes direct benefits, such as nutritional gifts or access to high-quality territories, which enhance the chooser's immediate reproductive output. In scorpionflies (Bittacus apicalis), males offer prey items as nuptial gifts during copulation, and females preferentially mate with males providing larger gifts, as these extend copulation duration and increase sperm transfer while supplying nutrition that boosts egg production. Territory quality also influences choice; for instance, females in many bird species select males defending resource-rich areas, correlating with higher offspring survival due to better provisioning. Indirect benefits via good genes arise when resource-holding traits signal heritable viability, as seen in pronghorn antelope where females choosing vigorous males produce faster-growing offspring with 0.32 higher weaning survival rates. Genetic criteria in mate choice often target alleles that improve offspring immune function or attractiveness. Preferences for diversity in the major histocompatibility complex (MHC) promote heterozygous offspring resistant to pathogens; in three-spined stickleback fish (Gasterosteus aculeatus), females use olfactory cues from MHC peptide ligands to select dissimilar males, with peptide diversity modulating preference strength (r = -0.60, P = 0.001). The sexy son hypothesis posits that females gain indirect benefits by producing attractive sons who sire more offspring; in polygynous systems, mating with high-quality males yields sons with elevated mating success, offsetting any reduced paternal care for daughters. Sensory bias occurs when pre-existing perceptual preferences, evolved for non-sexual functions, are co-opted for selection. In guppies ( reticulata), females' attraction to orange spots on males likely stems from a bias for orange fruit or , explaining 94% of inter-population variation in preferences (P = 0.0004). Similarly, in green swordtail fish (Xiphophorus helleri), female preference for elongated caudal fins (swords) reflects an ancestral bias for larger body size, as swordless sisters from sworded lineages still prefer swords, indicating exploitation of a pre-existing sensory tuning. Assessment processes involve comparing potential mates either sequentially (one at a time, common in natural encounters) or simultaneously (multiple options, as in lab tests). In the green swordtail, sequential assessment leads to weaker preferences for male body size compared to simultaneous setups, where direct comparisons amplify selectivity. Choosiness incurs costs, including increased predation risk during mate inspection; female Pacific field crickets (Gryllus coefficient) reduce time inspecting novel males near predators, trading accuracy for safety. Recent research employs computational models to simulate algorithms, revealing how multivariate preferences constrain evolution. Agent-based simulations show that preferences for multiple evolve slowly under indirect selection, with direct benefits accelerating divergence only when costs are low. Endocrine disruptors, such as (BPA) and , alter these processes; in guppies, developmental exposure to reduces female preferences for courting males, while BPA in shifts female choice toward control males, disrupting natural signaling (e.g., reduced association time by 20-30%). These findings highlight environmental impacts on choice criteria from studies.

Parental Care and Familial Interactions

Forms of Parental Care

Parental care in animals encompasses a of behaviors where parents invest time, , or resources to enhance survival and development, ranging from no care to extensive cooperative efforts. In many species, such as numerous , receive no parental investment post-fertilization, relying entirely on environmental cues for survival. Female-only care predominates in mammals, where mothers provide , , and provisioning due to the demands of and . Male-only care occurs in select taxa, exemplified by where males incubate embryos in a brood pouch and release fully formed young. Biparental care, involving both parents in , feeding, and defense, is common in and some mammals like wolves, while alloparental care extends to non-breeding , as seen in cooperatively breeding where subordinates assist in chick provisioning. Robert Trivers' parental investment theory posits that the sex exhibiting greater obligatory investment—such as larger gametes in females or prolonged care—becomes more selective in , as additional opportunities carry higher opportunity costs compared to further parental effort. This theory highlights trade-offs between current reproduction (investing in existing offspring) and future reproduction (seeking new mates), where heightened parental commitment can reduce remating chances, particularly for the investing sex. Benefits of include substantially elevated offspring survival; for instance, biparental care in birds often results in higher fledging success compared to uniparental regimes, through divided labor in provisioning and predator vigilance. However, costs accrue via depleted energy reserves and elevated predation risk to caregivers, potentially lowering parental lifespan or future breeding output. Ecological factors profoundly shape the evolution of , with harsher environments—characterized by scarce resources or high predation—favoring intensified investment to bolster offspring viability. In such settings, biparental feeding in species like the ensures nestlings receive adequate nutrition amid short, demanding breeding windows in polar regions. Recent research elucidates hormonal underpinnings, revealing that surges during breeding to mediate care behaviors, promoting nest attendance and offspring provisioning in both avian and mammalian parents. exacerbates these dynamics by compressing breeding seasons—single-brooded birds have shortened them by approximately two days per decade since the 2000s—constraining care duration and feasibility, often resulting in reduced provisioning rates and lower offspring recruitment. Recent studies as of 2025 further indicate that varying weather conditions influence offspring production and recruitment in species like the , affecting strategies.

Parent-Offspring Conflict

Parent-offspring conflict arises from the differing evolutionary interests between parents and their offspring regarding the allocation of parental resources, as first theorized by in 1974. Trivers posited that offspring are related to themselves by a coefficient of relatedness (r) of 1, maximizing their own fitness by demanding the maximum possible investment from parents, whereas parents are related to each offspring by r=0.5 on average, leading them to optimize investment across all current and future offspring for gains. This asymmetry results in offspring consistently seeking more resources than parents are selected to provide, creating an inherent tension mediated by the principles of . One key manifestation of this is in begging behaviors, where young animals signal their needs to elicit provisioning from parents. In avian species, such as songbirds, nestlings intensify calls and postures to demand , often exaggerating hunger to secure a larger share, while parents adjust feeding based on perceived need to balance investment across the brood. Similarly, conflicts emerge in mammals, particularly , where infants resist maternal efforts to terminate to prolong dependency and extract further resources, as observed in free-ranging rhesus macaques where infants exhibit tantrums and prolonged clinging during weaning attempts. Parents resolve these conflicts by assessing offspring signals that are evolutionarily honest, often because begging incurs significant costs that prevent unchecked exaggeration. For instance, in nestlings, elevated begging reduces cell-mediated , imposing an immunological cost that ensures signals reliably indicate need and allows parents to allocate resources efficiently without over-investing in deceptive offspring. In species prone to extreme outcomes, such as the , parents actively suppress aggressive offspring behaviors that could lead to resource monopolization, intervening to prevent the dominant chick from fatally attacking siblings during food shortages, thereby maintaining brood viability. Empirical genetic models further illustrate how conflict intensity varies with reproductive parameters like litter or clutch size. In theoretical frameworks, larger litters amplify the parent's incentive to distribute resources evenly, heightening over individual demands, as offspring push for more while parents favor quantity over per-offspring quality; simulations show that genetic correlations between litter size and offspring viability can mitigate this by aligning optima, but unresolved tensions persist in high-litter species. Recent research highlights epigenetic mechanisms influencing parent-offspring , particularly through maternal effects that modulate demands post-conception. Studies since 2010 demonstrate that variations in maternal care alter patterns in brains, affecting responses and resource-seeking behaviors during critical periods like , thereby shaping the intensity of without direct genetic changes. These transgenerational effects underscore how environmental cues from can epigenetically tune strategies to balance familial tensions.

Sibling Rivalry and Brood Parasitism

refers to the intense competition among offspring within the same brood for limited parental resources, such as food, which can lead to aggressive interactions and even in some . This behavior evolves primarily under conditions of resource scarcity, where the benefits of eliminating competitors outweigh the costs for the surviving offspring. In birds like eagles, facultative occurs when the older chick attacks and kills the younger one if food is insufficient, allowing the dominant sibling to monopolize and improve its own chances. Conversely, asynchronous hatching—where eggs hatch at staggered intervals—serves as an insurance strategy for parents, creating size hierarchies that facilitate brood reduction through starvation or aggression only when resources are limited, thus optimizing offspring quality without obligatory killing. Mechanisms of sibling rivalry often involve physical aggression and dominance based on age or size differences, with the larger sibling gaining priority access to food deliveries. Parents may tolerate such aggression if the net fitness benefits, such as producing a single high-quality offspring, exceed the costs of intervention, as modeled in theoretical frameworks that balance and . These models demonstrate that parental restraint evolves when sibling competition enhances overall brood productivity under variable environmental conditions. Brood parasitism represents an extreme extension of competitive strategies, where individuals exploit the of others by laying eggs in foreign nests, thereby avoiding direct investment in rearing. Conspecific brood parasitism occurs within the same species, as seen in waterfowl like ruddy ducks, where parasitic eggs are added to host clutches, intensifying resource competition among nestlings without eviction. In contrast, interspecific brood parasitism involves different species, such as common cuckoos laying eggs in reed warbler nests, where the parasitic chick often evicts host eggs or chicks using its oversized gape to push them out, securing sole access to provisions. Similarly, hawk-cuckoo nestlings employ eviction tactics to eliminate host offspring shortly after hatching. Hosts have evolved defenses against , including egg rejection, where adults recognize and eject foreign eggs based on differences in color, pattern, or size. This behavior is a key counteradaptation in the between parasites and hosts. Parasites respond with egg to evade detection; for instance, eggs feature spots that closely match those of many host species, reducing rejection rates. Despite these adaptations, imposes severe costs on hosts, often resulting in substantial reductions in nesting success due to complete brood failure or partial loss of offspring, as seen in up to 79% lower breeding success in parasitized nests of species like the black-backed water tyrant. In recent decades, has influenced dynamics by causing phenological mismatches in migration and breeding timings between parasites and hosts. Since the , warmer springs have advanced host laying dates more rapidly than those of brood parasites like the , leading to decreased success as parasites arrive too late to exploit peak host nesting periods. These shifts highlight how environmental changes can disrupt long-established coevolutionary interactions.

Social Behaviors and Kinship

Kin Selection and Inclusive Fitness

Kin selection is an evolutionary process whereby favors traits that enhance the of an 's relatives, thereby promoting the spread of shared genes even if the behavior reduces the actor's direct . This theory, developed by , addresses the puzzle of —behaviors that appear to benefit others at a personal cost—by emphasizing genetic relatedness as a key factor in social interactions. evolves not through self-sacrifice for its own sake, but because aiding indirectly boosts the propagation of the altruist's genes. Hamilton's framework shifted the focus from classical Darwinian selection, which prioritizes personal reproduction, to a broader . Central to kin selection is the concept of , which combines an individual's direct (the number of produced) with indirect (the additional conferred to relatives, devalued by the coefficient of relatedness r). This measure captures how can "reproduce" through the success of kin, resolving apparent paradoxes in . Hamilton formalized this in his seminal rule: a for will spread if rB > C, where r is the genetic relatedness between the actor and recipient (ranging from 0 for unrelated individuals to 1 for twins or clones), B is the benefit to the recipient, and C is the cost to the actor. The inequality quantifies when the indirect benefits outweigh the direct costs, allowing selection to favor apparently selfless acts. This rule has become a for modeling across taxa. Empirical support for is evident in the origins of , particularly in like bees, where workers forgo personal reproduction to raise siblings. Under haplodiploid sex determination, females share 75% relatedness with full sisters but only 50% with their own hypothetical offspring, making sister-rearing a higher strategy. This asymmetry, predicted by , explains the repeated evolution of sterile worker castes in social insects and has been validated through relatedness estimates in wild populations. Such patterns demonstrate how can drive complex social structures from simple genetic principles. Although influential, kin selection has encountered critiques and refinements, notably debates over multilevel selection. Since the mid-2000s, culminating in 2010, and colleagues argued that group-level processes, rather than strict gene-level relatedness, better explain eusociality's origins, sparking controversy over inclusive fitness's sufficiency. The debate persists as of 2025, with proponents of kin selection defending its explanatory power through mathematical and empirical responses, while no consensus has emerged on the primacy of either approach. Refinements include the , where a single both produces a recognizable trait (the "greenbeard") and biases aid toward bearers, enabling without relying on average population relatedness. These discussions highlight ongoing efforts to integrate kin selection with broader evolutionary mechanisms. Applications of kin selection extend to human behaviors, where experimental evidence shows stronger toward closer kin across cultures, consistent with Hamilton's predictions. In , the theory informs management of social species; for instance, maintaining optimal relatedness in honeybee colonies enhances queen production and colony resilience against stressors like habitat loss.

Kin Recognition Mechanisms

mechanisms enable animals to distinguish relatives from non-relatives, facilitating behaviors such as and that enhance . These mechanisms rely on cues that correlate with genetic relatedness, processed through sensory modalities like olfaction and . Genetic cues for kin recognition often involve phenotypic matching, where individuals compare traits of others to a template derived from self or familiar . In self-referent phenotype matching, use their own as the reference; for instance, mice recognize by matching urinary odors influenced by (MHC) genes to their own MHC profile, promoting MHC-dissimilar to avoid . Conversely, familiar kin recognition builds on early exposure, as in mice imprinting on familial MHC odors during development to identify siblings and facilitate communal nesting. Environmental cues provide indirect indicators of relatedness, such as spatial proximity or learned associations. Nestmates in social groups are often assumed to be kin due to shared location, reducing the need for precise genetic assessment; Belding's ground squirrels (Urocitellus beldingi), for example, preferentially aid nearby relatives in alarm calling and territory defense based on spatial clustering. Learned associations, like imprinting, allow recognition through familiarity; in birds such as European storm-petrels (Hydrobates pelagicus), olfactory imprinting on family odors during early life enables adults to distinguish kin from non-kin, supporting during . Olfactory cues are a primary method across taxa, often tied to genetic or environmental signals. Atlantic salmon (Salmo salar) and coho salmon (Oncorhynchus kisutch) use population-specific pheromones from natal streams, imprinted during juvenile stages, to recognize and home to kin-related groups, minimizing straying and enhancing spawning success. Visual cues, though less ubiquitous, play a role in visually oriented species; rhesus macaques (Macaca mulatta) spontaneously discriminate unfamiliar paternal half-siblings from non-kin by facial similarity, spending more time inspecting same-sex non-kin faces as potential rivals. Errors in can impose significant costs, including from mating with close relatives or wasted toward non-kin. In Belding's ground squirrels, reliance on spatial cues leads to occasional misrecognition of distant relatives as closer kin, potentially reducing the efficiency of nepotistic behaviors like predator . Such errors highlight the trade-offs in mechanism reliability, where over-inclusive recognition may favor caution in high-risk environments. Recent advances in genomic sequencing have illuminated the accuracy of these mechanisms, particularly in . Post-2010 studies using parentage analysis in species like (Danio rerio) have validated via olfactory and visual cues in discriminating full siblings from unrelated individuals, confirming phenotypic matching against genetic pedigrees.

Cooperation and Altruism

in behavioral ecology refers to behaviors where individuals or groups engage in actions that benefit others at a potential cost to themselves, particularly when those others are non-relatives, contrasting with mechanisms that favor relatives based on shared genes. Such non-kin often evolves through mechanisms that ensure long-term benefits, such as reciprocity or mutual gain, allowing individuals to overcome evolutionary challenges like the risk of . , in this context, describes costly behaviors that enhance the of non-kin recipients, with true altruism emerging when the actor gains no direct or indirect genetic benefit, though empirical cases often involve subtle returns. Reciprocal altruism, first formalized as a mechanism for non-kin cooperation, involves individuals providing benefits to others with the expectation of future reciprocation. In vampire bats (Desmodus rotundus), for instance, unsuccessful foragers regurgitate blood meals to roost-mates who failed to feed, with recipients more likely to return the favor in subsequent nights, fostering stable alliances among unrelated individuals. This system relies on repeated interactions and memory of past exchanges to enforce reciprocity, preventing cheating. Mutualism, another key type, entails simultaneous or ongoing benefits without strict reciprocity, as seen in cleaner fish-client fish interactions where cleaner wrasses (Labroides dimidiatus) remove parasites from larger fish in exchange for access to food, though cleaners sometimes cheat by eating client mucus, prompting clients to switch partners. Within species, cooperation manifests in group , where collective increases success rates for participants. In African lions (Panthera leo), prides collaborate to pursue large prey like buffalo, with roles divided such that some individuals flush or immobilize the target while others deliver the kill, yielding higher per capita energy intake than solitary efforts despite risks of injury. Enforcement of such cooperation often involves punishment mechanisms; in like chimpanzees (Pan troglodytes), dominant individuals monitor and aggress against free-riders during group tasks, such as nut-cracking or , thereby stabilizing cooperative norms. Between species, symbiotic mutualisms exemplify interspecific cooperation, such as the relationship between and , where protect aphids from predators and facilitate their dispersal in return for secretions, a nutrient-rich that forms a significant portion of the ' diet. Partner choice models explain the stability of these interactions, positing that participants select and punish unreliable partners, akin to market dynamics, which has been modeled to predict when mutualisms persist over evolutionary time. Evolutionary puzzles surrounding non-kin cooperation, such as the —where mutual yields mutual benefits but defection tempts higher individual gains—have been addressed through strategies like tit-for-tat, which starts with and mirrors the opponent's previous move, outperforming other tactics in computational tournaments by promoting reciprocity in iterated . Reputation-based systems further resolve these dilemmas via image scoring, where individuals track others' cooperative histories and preferentially aid those with positive reputations, leading to the evolution of indirect reciprocity even without direct returns. Recent research highlights emerging influences on cooperation, including the host , which can modulate social behaviors by altering nutrient processing or immune responses that affect group interactions, as observed in social bees where gut bacteria promote foraging . In conservation contexts, human-animal has been documented, such as dolphins (Tursiops truncatus) in , , signaling fish schools to fishermen, resulting in larger catches for both and sustained interspecific alliances over generations.

Conflicts and Advanced Social Dynamics

Sexual and Intersexual Conflict

Sexual conflict arises when the evolutionary interests of males and females diverge, particularly over decisions and , leading to traits that benefit one sex at the expense of the other. This intersexual antagonism often manifests in pre-copulatory behaviors, such as , where males force despite female resistance, as seen in waterfowl like , where unpaired males pursue extrapair copulations that can injure females and reduce their efficiency. Post-copulatory conflicts involve mechanisms to manipulate fertilization, including genital structures that hinder rival , such as spines in male that block female genitalia after . Geoffrey Parker's foundational model emphasized these conflicts as an extension of , where traits evolve through an , imposing costs like reduced female lifespan or increased predation risk on . Sexual conflicts are categorized into interlocus and intralocus types. Interlocus conflict occurs when traits in one sex evolve in response to traits in the other sex, driving antagonistic coevolution; for instance, in bed bugs (), males use by piercing the female's abdomen to bypass her genital tract, prompting females to evolve protective structures like the spermalege to mitigate injury and infection risks. This results in a perpetual evolutionary chase, resolvable through or mate guarding, which allows females to dilute unwanted sperm or secure paternal investment. In contrast, intralocus sexual conflict stems from shared genetic loci where alleles beneficial in one sex are detrimental in the other, leading to suboptimal compromises in sexually dimorphic traits. Representative examples illustrate these dynamics across taxa. In fruit flies (), male courtship harassment imposes fitness costs on females by diverting time from oviposition and increasing energy expenditure, though females can evolve resistance without eliminating male benefits entirely. Avian sexual dimorphism, such as elongated male tails in barn swallows (Hirundo rustica), arises from interlocus conflict, as these ornaments enhance male mating success but, when expressed in females via , reduce aerodynamic efficiency and increase mortality. Recent genomic studies provide evidence for sexually antagonistic selection, identifying alleles with opposite effects on in males and females, such as variants influencing reproductive traits and disease susceptibility in humans. These findings underscore how unresolved conflicts contribute to intralocus genetic variance, maintaining dimorphism despite costs.

Spiteful Behaviors

Spiteful behaviors in behavioral ecology refer to interactions in which an actor incurs a direct cost (C > 0) to impose on a recipient, resulting in a net reduction in the actor's , as captured by the extended form of Hamilton's rule: rB - C < 0, where B represents the negative effect on the recipient (B < 0), C is the positive cost to the actor (C > 0), and r is their genetic relatedness. This contrasts with (rB - C > 0). Such behaviors are theoretically rare because typically acts against traits that reduce the actor's without compensatory benefits, requiring conditions like negative relatedness (r < 0) between actor and recipient to favor their . Negative relatedness arises when actors interact more frequently with individuals carrying fewer copies of their genes than average, often due to local or structured populations, allowing spite to spread by disproportionately harming less-related competitors. Seminal theoretical work by formalized this framework, while later models, such as Grafen's geometric approach to relatedness, clarified how spatial structure or kin discrimination can generate the necessary asymmetry for spite. Empirical detection of spite is challenging, as behaviors must be verified to lack direct benefits to the and target non-kin or negatively related individuals, distinguishing them from selfish . A well-documented example occurs in microbial communities, where bacteria like Pseudomonas aeruginosa produce bacteriocins—toxic proteins released at a metabolic cost to the producer—that kill or inhibit susceptible competitors, particularly in structured environments like biofilms. This spiteful toxin production maintains by eliminating unrelated strains, with studies showing higher bacteriocin diversity in natural populations where local amplifies negative relatedness. In biofilms, such interactions escalate territorial aggression, as producers target non-kin to secure resources, though the cost limits spite to high-density settings. Recent models (as of 2024) indicate that spite evolves less readily than in scenarios with interdependent costs, while dynamic interaction networks facilitate its spread without requiring negative relatedness. In animals, spite manifests through greenbeard mechanisms, where a encodes both a recognizable (the "beard") and a to harm those lacking it, even among , thereby favoring the gene's spread and preserving diversity against cheaters. Theoretical models predict this rejection evolves when the trait enables precise discrimination, as in hypothetical or observed cases like flocculation genes that promote aggregation among carriers while excluding non-carriers. Another empirical case involves polyembryonic wasps associated with ecosystems, where sterile "soldier" castes—derived from the same —engage in spiteful , destroying full siblings to bias sex ratios toward reproductive sisters, incurring a cost but reducing competition from males under negative relatedness within clones. These soldiers preferentially eliminate less-related embryos, supporting spite's role in resolving intragenomic conflicts. Overall, spite evolves sparingly but contributes to by countering the spread of exploitative genotypes, as seen in dynamics that prevent clonal dominance in biofilms. In greenbeard systems, it enforces among carriers, stabilizing traits against . Despite rarity, post-2000 studies in microbes underscore spite's in viscous populations, where local harm sustains polymorphism without requiring altruism's benefits.

Dynamics in Social Insects

Eusociality in social insects, such as and , is characterized by a reproductive division of labor between and non-reproductive workers, cooperative brood care among colony members, and overlapping generations within the colony. These traits enable highly organized societies where workers forgo personal reproduction to support the queen's offspring, fostering colony-level success in species like the honeybee (Apis mellifera) and various genera. Despite this cooperation, conflicts arise within eusocial colonies, particularly between and workers over to male and female . In haplodiploid , workers are more closely related to sisters (relatedness coefficient r = 0.75) than to brothers (r = 0.25), leading them to bias sex s toward females, while favor a 1:1 since they are equally related to both sexes (r = 0.5). This queen-worker conflict over sex s manifests in behaviors where workers selectively rear more female brood, as observed in many . To mitigate worker and maintain harmony, policing behaviors evolve, in which workers eat eggs laid by other workers, favoring queen-laid eggs; this mutual policing is prominent in with multiply mated , reducing relatedness among worker-produced males. The hypothesis posits that single queen mating promotes by maximizing average colony relatedness, creating a "window" for the of sterile castes through enhanced benefits for worker . supports this, as ancestral is inferred in all major eusocial lineages, including and , where lifetime single mating aligns with the transition to obligatory . Conflicts persist due to selfish genetic elements that disrupt colony harmony, such as B chromosomes or paternal sex ratio (PSR) elements, which bias transmission by eliminating rival genomes and promoting their own spread, sometimes at the cost of colony fitness in wasps and ants. In honeybees, queen mandibular pheromone (QMP) resolves worker reproduction attempts by suppressing ovarian development and egg-laying in workers, ensuring queen dominance through chemical signaling. Recent genomic advances reveal that caste determination involves epigenetic mechanisms like , which differentially regulates between queens and workers; for instance, methylomes in such as Camponotus floridanus show caste-specific patterns enriched in exons of development-related genes. Recent studies (as of 2025) highlight how innovations in larval feeding enhance queen-worker dimorphism, resolving conflicts through specialized , and intragenomic conflicts via in caste determination, such as in honeybees. further influences colony dynamics, with rising temperatures altering rates and brood survival, potentially destabilizing communities through increased nest abandonment and shifts in interactions.

Communication and Signaling

Signal Types and Functions

Animal signals in behavioral ecology are categorized by their sensory modalities, which determine how information is transmitted between individuals in diverse ecological contexts. Visual signals involve displays that are perceived through sight, such as the elaborate tail feathers of male peacocks (Pavo cristatus), which are used to attract mates by showcasing vibrant colors and patterns during rituals. Auditory signals rely on sound production and reception, exemplified by the species-specific calls of male frogs like the túngara frog (Engystomops pustulosus), which advertise reproductive readiness and territorial boundaries to females and rivals. Chemical signals, often in the form of pheromones, convey information via olfactory cues; for instance, alarm pheromones released by (Aphidoidea) alert nearby colony members to predator threats, prompting defensive behaviors. Tactile signals involve physical contact or vibrations, such as the in (Formicidae), where abdominal rubbing produces vibrations that coordinate or alarm responses within nests. These modalities serve various functions essential for and in ecological settings. Signals facilitate mate attraction by conveying genetic quality or availability, as seen in the synchronized flashes of fireflies (Photinus spp.), where pulse patterns enable species recognition and courtship initiation. Territory defense often employs aggressive displays, such as the auditory challenges of songbirds like the (Sayornis phoebe), which deter intruders through vocal repertoires that signal residency and strength. Alarm signaling coordinates group responses to dangers; vervet monkeys (Chlorocebus pygerythrus) produce distinct calls for different predators—low grunts for leopards, high trills for eagles, and chutters for —eliciting appropriate escape behaviors like looking up or climbing trees. The evolutionary origins of these signals trace back to ritualization, a process where incidental movements, known as intention movements, become exaggerated and stereotyped for communicative purposes, as described by Niko Tinbergen in his foundational work on . For example, a bird's partial wing lift before flight may evolve into a full display for threat assessment. The reliability of signals is maintained through inherent costs, such as energy expenditure in producing bright visual ornaments or the predation risk from conspicuous auditory calls, which prevent low-quality individuals from mimicking them effectively. Specific examples highlight the integration of modalities and functions. In fireflies, bioluminescent flashes not only aid species recognition during mate attraction but also incorporate chemical pheromones for close-range confirmation, ensuring precise pairing in low-light environments. Seismic signals in spiders, such as the vibratory thumps and scrapes produced by male (Schizocosa ocreata) on substrates, function in to assess female receptivity without visual exposure, reducing interception by rivals or predators. In modern contexts, interference disrupts these signals, particularly visual ones. from urban sources masks bioluminescent displays in fireflies and alters navigation, leading to reduced success and declines, as documented in studies from the early 2000s onward. Similarly, artificial lighting interferes with nocturnal visual cues, potentially affecting and predator avoidance in fragmented habitats. Recent research as of 2025 has also revealed dynamic shifts in signal modalities, such as switching from auditory to visual displays in noisy environments to maintain communication .

Honesty, Deception, and Sensory Exploitation

In behavioral ecology, honest signaling refers to communication where the signal reliably conveys about the sender's , often enforced by inherent costs that prevent low-quality individuals from mimicking it. Index signals, such as the size of a in male collared flycatchers (Ficedula albicollis), directly correlate with physiological traits like testosterone levels, providing receivers with accurate cues of the sender's competitive ability and health. This reliability arises because the signal is an unavoidable byproduct of the underlying condition, making difficult without physiological trade-offs. The handicap principle further explains honesty through costly displays that only high-quality individuals can afford, thereby stabilizing signal reliability in competitive contexts like mate attraction. Proposed by Zahavi in 1975, this mechanism posits that exaggerated traits, such as the elaborate tail feathers of peacocks (Pavo cristatus), impose survival costs like increased predation risk or energetic demands, ensuring that only fit males can maintain them without compromising viability. Empirical support comes from studies showing that peacock tail condition predicts mating success, as poorer individuals suffer higher viability costs from bearing such handicaps. Deception, in contrast, involves senders providing misleading signals to exploit receivers, often at the expense of the latter's . A classic example is in fireflies of the genus Photuris, where females imitate the flashes of Photinus species to lure males as prey, capitalizing on the receivers' pre-existing response to sexual signals. This bluffing strategy succeeds because the deceptive signal mimics an honest one, leading to false alarms where prey approach under the illusion of a opportunity, though repeated deception risks eroding signal trustworthiness in the population. enhances such deception, as seen in predators that blend into environments to , where the absence of signal itself misleads prey about danger presence. Sensory exploitation occurs when signals evolve to hijack receivers' pre-existing sensory es, unrelated to the signal's adaptive value, leading to unintended responses. In fish (Xiphophorus helleri), the male's sword-like tail extension exploits a female preference for elongated objects, which predates the trait's evolution and likely stems from biases toward detecting predators or food items. Experimental manipulations confirm that females without prior exposure to swords still prefer them, indicating the bias is innate and not learned through , allowing sensory exploitation to drive rapid trait evolution. Theoretical models emphasize receiver as a key driver of both and in signal . Guilford's 1990 argues that signals are shaped by the cognitive and sensory predispositions of receivers, where pre-existing biases can be co-opted for manipulative ends, but is maintained if mismatches impose detection costs on deceivers. carries inherent costs, such as energetic waste from false alarms in predator detection systems, where receivers responding to unreliable cues forgo opportunities or incur unnecessary flight responses, selecting against excessive bluffing over evolutionary time. Empirical studies illustrate these dynamics in diverse taxa, including web decorations in orb-weaving spiders (Cyclosa spp.), where silk stabilimenta or detritus additions deceive avian predators by mimicking bird droppings or UV-reflective cues, deflecting attacks from the spider's hub while potentially attracting prey. In urban environments, post-2010 research on songbirds like house finches (Haemorhous mexicanus) shows adaptations where males reduce trill rates and adjust amplitude in noisy habitats to maintain signal efficacy without excessive conspicuousness, potentially minimizing detection by urban predators through subtler acoustic crypsis.

References

  1. [1]
    11: Behavioral Ecology
    ### Definition and Key Concepts of Behavioral Ecology
  2. [2]
    Behavioral Ecology - Biological Principles
    Behaviors are defined as actions in response to stimuli (singular, stimulus, which is something that causes a response), and almost all organisms exhibit some ...<|control11|><|separator|>
  3. [3]
    “It Felt More like a Revolution.” How Behavioral Ecology Succeeded ...
    Apr 25, 2022 · Behavioral ecology focused on understanding selective forces that have shaped behavior over evolutionary time in its current ecological context.Abstract · A New Golden Age: Young... · A Discipline Emerges...
  4. [4]
    Behavioral Ecology - an overview | ScienceDirect Topics
    Behavioral ecology is strongly informed by a series of theoretical breakthroughs developed in the early 1960s and 1970s in the evolutionary analysis of social ...
  5. [5]
    Behavioral Ecology - an overview | ScienceDirect Topics
    Behavioral ecology is defined as the study of the adaptive aspects of behavior, focusing on how behaviors influence fitness and are shaped by environmental ...
  6. [6]
    Behavioural ecology - Latest research and news - Nature
    Behavioural ecology is the study of behavioural interactions between individuals within populations and communities, usually in an evolutionary context.
  7. [7]
    Patch quality and habitat fragmentation shape the foraging patterns ...
    Jul 17, 2022 · Due to the potentially high costs of moving between patches, fragmented habitats are predicted to complicate foraging decisions of many animals.
  8. [8]
    Beyond buying time: the role of plasticity in phenotypic adaptation to ...
    Jan 28, 2019 · How populations and species respond to modified environmental conditions is critical to their persistence both now and into the future, ...
  9. [9]
    Integrating biogeography and behavioral ecology to rapidly ... - PNAS
    Apr 5, 2023 · This union of disciplines will advance efforts to predict biodiversity's responses to climate change and habitat loss through a deeper understanding.<|control11|><|separator|>
  10. [10]
    [PDF] Tinbergen, N. 1963. “On aims and methods of ethology.”
    Tinbergen, N. 1963. “On aims and methods of ethology.” Zeitschrift für Tierpsychologie 20:410-433.Missing: questions | Show results with:questions
  11. [11]
    The Significance of Clutch‐size - Lack - 1947 - Wiley Online Library
    Lack, D. 1947. The significance of clutch-size in the Partridge. J. Animal Ecol. (in press). 10.2307/1503Missing: behavioral | Show results with:behavioral
  12. [12]
    “It Felt More like a Revolution.” How Behavioral Ecology Succeeded ...
    I will show how behavioral ecology took the role of legitimate heir to ethology by rebuilding a theoretical core and an intellectual sense of community.
  13. [13]
    Evolution and the Theory of Games
    In this 1982 book, the theory of games, first developed to analyse economic behaviour, is modified so that it can be applied to evolving populations.
  14. [14]
    25 years of Behavioral Ecology - Oxford Academic
    Dec 1, 2013 · Behavioral ecology is a theoretically driven science and has a long history of theoretical modeling. In their article on reproductive sharing ...
  15. [15]
    Genomic tools for behavioural ecologists to understand repeatable ...
    Feb 12, 2018 · Here, we offer a critical review of when molecular techniques may yield new insights, and we provide specific guidance on how and whether the latest tools ...
  16. [16]
    The Role of Behavioral Ecotoxicology in Environmental Protection
    Apr 14, 2021 · A wide variety of contaminants and other environmental stressors adversely affect organismal behavior and subsequent ecological outcomes.<|control11|><|separator|>
  17. [17]
    On the instability of evolutionary stable strategies - ScienceDirect.com
    The principal assumption underlying evolutionary stable strategies is an infinite population (Maynard Smith, 1982, p. 20)1. The question of biological ...Missing: critiques | Show results with:critiques
  18. [18]
    [PDF] E ects of Finite Populations on Evolutionary Stable Strategies
    Thus, they con- clude that evolutionary game theory loses predictive power once these assumptions are relaxed. In this paper, we concentrate on the first (and ...
  19. [19]
    frequency-dependent sexual selection in male bluegill sunfish
    Evolution of alternative reproductive strategies: frequency-dependent sexual selection in male bluegill sunfish. Mart R. Gross.
  20. [20]
    [PDF] Central Place Foraging - Chittka Lab
    Orians, G. H., & Pearson, N. E. (1979). On the theory of central place foraging. In D. J. Horn, G. R. Stairs, &. R. D. Mitchell (Eds.), Analysis of ...
  21. [21]
    [PDF] Optimal Foraging, the Marginal Value Theorem - Paul Seabright | .com
    Two earlier publications (Krebs, Ryan, and Charnov, 1974; Charnov, Orians, and Hyatt, 1976) derived a simplified version of the movement rule given in (4) and ...
  22. [22]
    [PDF] Caraco et al 1980.pdf - Stewart Calculus
    We report laboratory experiments with yellow-eyed juncos (Junco phaeonotus) revealing that the birds' foraging preferences for variable rewards respond not only ...
  23. [23]
    (PDF) Optimal foraging: Movement patterns of bumblebees between ...
    Aug 7, 2025 · Nevertheless, the optimal forage theory, whereby bee foragers are predicted to remain in areas with high floral resources to meet their energy ...
  24. [24]
    (PDF) Hunter-Gatherer Foraging Strategies: Ethnographic and ...
    Aug 5, 2025 · PDF | On Jan 1, 1981, Bruce Winterhalder and others published Hunter-Gatherer Foraging Strategies: Ethnographic and Archeological Analyses ...
  25. [25]
    [PDF] Behavioral decisions made under the risk of predation
    When the best areas for foraging are also the most dangerous, the forager must trade off energy gain against the.risk of predation in deciding where to feed.
  26. [26]
    Effect of an Invasive Plant and Moonlight on Rodent Foraging ...
    Our findings illustrate that foraging rodents, well known to be risk-averse during moonlit nights, are also affected by the presence of an invasive plant. This ...
  27. [27]
    [PDF] The Evolution of Diversity in Avian Territorial Systems
    The paper presents a theory for the evolution of territoriality, where defendability of resources like food and mates is key, and competition increases ...
  28. [28]
    The economics of territory selection - ScienceDirect.com
    Dec 15, 2020 · For territoriality to occur, resources should be economically defendable, i.e., benefits obtained should outweigh costs of ownership (Brown, ...
  29. [29]
    The Evolution of Diversity in Avian Territorial Systems - jstor
    The evolution of avian territoriality is influenced by competition, economic defendability, and the adaptive value of aggressiveness, with defendability being ...
  30. [30]
    The deterrent effect of bird song in territory defense - PMC - NIH
    The banded wren is a territorial, insectivorous, nonmigratory neotropical oscine. Banded wrens produce a repertoire of approximately 20 song types, with each ...
  31. [31]
    Residency effects in animal contests - Biological Sciences - Journals
    The question of why territorial residents usually win asymmetrical owner-intruder contests is critical to our understanding of animal contest evolution.
  32. [32]
    The Economics of Territory Defence in the Pied Wagtail, Motacilla alba
    (1) Pied wagtails defended winter feeding territories along a river. They fed on insects that were washed up onto the river banks.Missing: spacing | Show results with:spacing
  33. [33]
    [PDF] From Hawks and Doves to Self-Consistent Games of Territorial ...
    The animal kingdom provides countless examples of the. “prior-residence effect,” the fact that individuals who ar- rived somewhere first appear to have a “ ...
  34. [34]
    Territorial defence and its seasonal decline in the speckled wood ...
    We show that male Pararge aegeria butterflies fight aggressively over ownership of sunspot territories in the ground layer of woodland.<|control11|><|separator|>
  35. [35]
    Dear enemies or nasty neighbors? Causes and consequences of ...
    ... meerkat groups exhibited territory exploration (visiting of sleeping burrows) ... Just like participation in territory defense, levels of ...
  36. [36]
    Urbanization has opposite effects on the territory size of two ...
    Apr 28, 2020 · Ground-sparrow territories were larger at the highly urbanized site than at the non-urbanized site. Wren territories were larger at the low ...
  37. [37]
    https://academic.oup.com/beheco/article/29/5/1004/4857217
  38. [38]
    On the Evolution of Mating Systems in Birds and Mammals
    These predictions are that (1) polyandry should be rare, (2) polygyny should be more common among mammals than among birds, (3) polygyny should be more ...
  39. [39]
    Where are the beachmasters? Unexpectedly weak polygyny among ...
    Nov 24, 2021 · Elephant seals are a textbook example of a highly polygynous mating system, with dominant 'beachmaster' males controlling harems of up to ...
  40. [40]
    Monogamy Rare In the Wild - National Audubon Society
    Feb 14, 2013 · But paternity testing suggests that the reverse is true: Scientists now believe that about 90 percent of bird species are socially monogamous, ...
  41. [41]
    Genetic evidence for extreme polyandry and extraordinary sex-role ...
    Moreover, the Gulf pipefish exhibits classical polyandry with the greatest asymmetry in reproductive roles (as quantified by variances in mating success) ...
  42. [42]
    Sneaker “jack” males outcompete dominant “hooknose” males ...
    Nov 11, 2013 · In many species, small “sneaker” males attempt to steal fertilizations while avoiding encounters with larger, more aggressive, dominant males.<|control11|><|separator|>
  43. [43]
    Extra‐pair paternity in birds - PMC - NIH
    On average, in those socially monogamous biparental species in which genetic polyandry has been found, 19% of offspring are found to have been sired by an extra ...
  44. [44]
    Prolonged mate guarding and sperm competition in the weevil ...
    Prolonged copulatory guarding is a well-described phenomenon in insects and is usually explained as a male adaptation to avoid sperm competition (Simmons, 2000; ...
  45. [45]
    Mate selection—A selection for a handicap - ScienceDirect.com
    It is suggested that characters which develop through mate preference confer handicaps on the selected individuals in their survival.
  46. [46]
    Female choice selects for extreme tail length in a widowbird - Nature
    Oct 28, 1982 · These results suggest that the extreme tail length in male long-tailed widowbirds is maintained by female mating preferences.
  47. [47]
    Quantitative genetic correlation between trait and preference ... - PNAS
    Our quantitative genetic data provide support for a role of postcopulatory female preferences in driving evolutionary divergence in sperm morphology, in much ...
  48. [48]
    Urban noise can alter sexual selection on bird song - PMC - NIH
    Jan 31, 2012 · Our data do show that urban noise can alter sexual selection pressures acting on bird singing behavior.Missing: sensory drive post- 2000
  49. [49]
    Good genes sexual selection in nature - PNAS
    Whether the mate sampling and choice performed by females in nature influences offspring performance is a controversial issue in theory and an open ...
  50. [50]
    Mate choice decisions of stickleback females predictably modified ...
    We show that structurally diverse MHC ligands interact with natural odors of male sticklebacks to predictably modify MHC-related mate choice.
  51. [51]
    Offspring Quality and the Polygyny Threshold: "The Sexy Son ...
    It was postulated that females mating with "attractive" males and suffering reduced reproductive success could ultimately gain an advantage through the success ...
  52. [52]
    [PDF] A possible non-sexual origin of mate preference: are male guppies ...
    Feb 20, 2002 · guppies for orange coloration on males has arisen as a result of a sensory bias for orange-coloured objects, perhaps orange-coloured fruit.
  53. [53]
    Female preference for swords in Xiphophorus helleri reflects a bias ...
    Female preference for males with a conspicuous “sword” ornament is ancestral, suggesting that male morphology has evolved in response to a preexisting bias.Missing: paper | Show results with:paper
  54. [54]
    The effect of experimental design on the measurement of mate choice
    Aug 29, 2014 · Differences in female preference for male body size in Poecilia latipinna using simultaneous versus sequential stimulus presentation designs.
  55. [55]
    Multivariate mate choice constrains mate preference evolution
    In our model, we could have used many alternative mate choice algorithms – for example, we could have had agents select partners by evaluating traits one by ...
  56. [56]
    Mate Choice, Sexual Selection, and Endocrine-Disrupting Chemicals
    Sep 11, 2017 · Mate Choice, Sexual Selection, and Endocrine-Disrupting Chemicals ... To follow is a brief synopsis of studies showing effects of developmental ...Sexual Selection: The... · Figure 1 · The Mpoa And Vmn: Effects Of...
  57. [57]
    Parenting in Animals - PMC - PubMed Central - NIH
    Animal parenting varies, including uniparental female care, shared care, and biparental care. Some animals show no care, while others have unique care systems.
  58. [58]
    (PDF) Parental Investment and Sexual Selection - ResearchGate
    PDF | On Jan 1, 1972, RL Trivers published Parental Investment and Sexual Selection | Find, read and cite all the research you need on ResearchGate.
  59. [59]
    Biparental care is more than the sum of its parts - NIH
    Our main finding was that offspring grew larger and were more likely to survive to adulthood when reared by both parents than a single parent.
  60. [60]
    Parental care in birds - ScienceDirect.com
    Oct 24, 2022 · Costs and benefits of parental care. Many of these services are demonstrably costly to parental time and energy budgets, in many cases to ...
  61. [61]
    Constrained flexibility of parental cooperation limits adaptive ... - NIH
    Parental care is predicted to evolve to mitigate harsh environments, thus adaptive plasticity of care may be an important response to our climate crisis.
  62. [62]
    Prolactin, body condition and the cost of good parenting: an ...
    Jul 25, 2006 · The pituitary hormone prolactin is thought to play an important role in the promotion of parental care in birds and mammals.
  63. [63]
    The effect of climate change on the duration of avian breeding ...
    Multi-brooded birds have prolonged their seasons by 4 days per decade, while single-brooded have shortened by 2 days. Changes in season lengths co-varied with ...
  64. [64]
    Parent-Offspring Conflict - ROBERT L. TRIVERS - Oxford Academic
    I present here a theory of parent- offspring relations which follows directly from the key concept of inclusive fitness and from the assumption that the ...
  65. [65]
    Begging the question: are offspring solicitation behaviours signals of ...
    We assess empirical support for the recent theory that begging advertises offspring need, that parents provision young in relation to begging intensity.
  66. [66]
    Physiological and behavioural responses to weaning conflict in free ...
    Our study provides the first evidence for an infant physiological stress response to weaning in a free-ranging population of mammals.
  67. [67]
    An immunological cost of begging in house sparrow nestlings
    Mar 10, 2010 · Nestlings forced to beg fiercely showed a reduction in immunocompetence with respect to control chicks, but the two groups showed no difference ...
  68. [68]
    Parent Blue-Footed Boobies Suppress Siblicidal Behavior of Offspring
    Abstract Behaviorally dominant nestlings routinely kill sibling nestmates in blue-footed booby (Sula nebouxii) broods during periods of food shortage.
  69. [69]
    Can number and size of offspring increase simultaneously?
    Mar 31, 2012 · A positive genetic correlation between direct genetic effects for litter size and offspring birth size can reduce parent-offspring conflict ...
  70. [70]
    Early-Life Experience, Epigenetics, and the Developing Brain - Nature
    Jun 11, 2014 · Here we will highlight evidence of dynamic epigenetic changes in the developing brain in response to variation in the quality of postnatal parent–offspring ...
  71. [71]
    The Evolution of Sibling Rivalry - Douglas W. Mock; Geoffrey A. Parker
    This book details the theory, field experiments, and natural history of sibling rivalry across a broad sweep of animals and plants.
  72. [72]
    Sibling aggression and brood reduction: a review
    This phenomenon is termed “facultative siblicide” and occurs in a wide range of bird species and at least one mammalian species.
  73. [73]
    Hatching asynchrony as a parental reproductive strategy in birds
    Mar 31, 2023 · Hatching asynchrony is a breeding strategy where birds hatch at different times, often leading to competitive disadvantages for later-hatched  ...
  74. [74]
    The Ecology of Avian Brood Parasitism | Learn Science at Scitable
    Brood parasitism may also be intraspecific, with eggs laid in other nests of the parasite's own species, or interspecific, with all eggs laid in the nests of ...
  75. [75]
    Kin selection and the evolution of conspecific brood parasitism - PNAS
    Brood parasitism has been viewed traditionally as an interaction that squarely pits the interests of the “parasite” against those of the host, leading perhaps ...
  76. [76]
    (PDF) Horsfield's Hawk-Cuckoo Nestlings Simulate Multiple Gapes ...
    Aug 6, 2025 · Nestlings of some brood parasitic birds evict hosts' eggs and young soon after hatching, thereby avoiding discrimination by hosts while ...<|control11|><|separator|>
  77. [77]
    Active defence mechanisms in brood parasitism hosts and their ...
    Jun 20, 2024 · The most virulent brood parasites are found among Cuculidae and Indicatoridae families, in which the parasite chick evicts or lethally injures ...Egg Recognition · Egg Rejection By Hosts · Chick Recognition
  78. [78]
    Impacts of brood parasitism by shiny cowbird Molothrus bonariensis ...
    Jul 27, 2023 · The most frequent cause of nest failures was deserted for brood parasitism ... host clutches or with only parasitic nestlings in the brood ...
  79. [79]
    Climate change effects on migration phenology may mismatch ... - NIH
    In conclusion, this study provides evidence that climate change may be affecting ecological interactions and coevolutionary dynamics between brood parasites ...Missing: 1990s | Show results with:1990s
  80. [80]
    KIN RECOGNITION: FUNCTIONS AND MECHANISMS A REVIEW
    Kin recognition involves discriminating kin, using cues, classifying conspecifics, and mechanisms like dishabituation or phenotype matching.
  81. [81]
    [PDF] Phenotypic Matching or Recognition Alleles? - Andrew Blaustein Lab
    There are four possible mechanisms proposed for kin recognition (reviewed by. Alexander 1979; Bekoff 1983; Dawkins 1982; Holmes and Sherman 1982). 1.Missing: MHC visual
  82. [82]
    MHC signaling during social communication - PMC - PubMed Central
    Possible phenotype matching systems using MHC-based odors and their effectiveness for the recognition of kin. Two kin recognition mechanisms that exist in ...
  83. [83]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC2781939/
  84. [84]
    The ontogeny of kin-recognition mechanisms in Belding's ground ...
    May 1, 2017 · Belding's ground squirrels, Urocitellus beldingi, use at least two mechanisms of kin recognition in nepotistic contexts: familiarity and phenotype matching.
  85. [85]
    Kin recognition and inbreeding avoidance in wild birds
    Identification of family members plays a primary role in the evolution of social behaviours such as nepotism, altruism and mate choice.
  86. [86]
    Evidence of chemically mediated population recognition in coho ...
    To test the hypothesis that population-specific pheromones guide adult salmonids to their natal streams, juvenile and adult coho salmon (Oncorhynchus ...
  87. [87]
    Monkeys Spontaneously Discriminate Their Unfamiliar Paternal Kin ...
    Aug 4, 2014 · Our results provide strong evidence for visual phenotype matching and the first demonstration in any primate that individuals can spontaneously ...
  88. [88]
    [PDF] Animal Behaviour - Jill M. Mateo
    Belding's ground squirrels, Urocitellus beldingi (Helgen et al. 2009), exhibit nepotism among certain classes of close female kin, including production of ...
  89. [89]
    Sexual conflict over mating and fertilization: an overview - PMC - NIH
    Sexual conflict is a conflict between the evolutionary interests of individuals of the two sexes (Parker 1979). A 'conflict of evolutionary interests' is ...Missing: Geoffrey | Show results with:Geoffrey
  90. [90]
    Sexual conflict in waterfowl: why do females resist extrapair ...
    Abstract. Forced copulation is a male reproductive strategy in a variety of animals but rare among avian species, with the notable exceptions of waterfowl.
  91. [91]
    ‪Geoff A Parker‬ - ‪Google Scholar‬
    Sexual selection and sexual conflict. GA Parker. Sexual selection and reproductive competition in insects (ed. MS Blum & NA …, 1979. 1925, 1979 ; Punishment in ...
  92. [92]
    Traumatic insemination and sexual conflict in the bed bug Cimex ...
    We conclude that traumatic insemination is probably a coercive male copulatory strategy that results in a sexual conflict of interests.
  93. [93]
    Sexual conflict - ScienceDirect.com
    Jun 3, 2019 · Parker's contribution focused purely on conflict between the sexes and pretty much defined the logic and the evolutionary expectations and ...
  94. [94]
    Making sense of intralocus and interlocus sexual conflict - PMC
    Intralocus sexual conflict and IRSC are evolutionary conflicts between males and females and are commonly discussed in the context of gonochorism (or dioecy in ...
  95. [95]
    Sexual harassment induces a temporary fitness cost but does not ...
    Jan 1, 2016 · Here we evaluate the acquisition of environmental information in groups of fruit flies challenged with various levels of male sexual harassment.
  96. [96]
    Male mate preference against tail-elongated females in the barn ...
    May 23, 2022 · We found that males significantly reduced the number of pairing displays when they were presented with tail-elongated female models compared to control female ...1 Introduction · 2 Methods · 4 Discussion<|separator|>
  97. [97]
    Systematic review reveals multiple sexually antagonistic ...
    Sexually antagonistic (SA) alleles have opposite effects in sexes, with 49 variants found affecting 21 complex traits and 17 disease risk/severity traits.
  98. [98]
    Contrasting effects of intralocus sexual conflict on sexually ... - PNAS
    The interaction of inter- and intralocus conflict thus keeps the sexes caught in a perpetual cycle of arms races, alternated by phases of conflict resolution.
  99. [99]
    Selfish and Spiteful Behaviour in an Evolutionary Model - Nature
    Dec 19, 1970 · Selfish and Spiteful Behaviour in an Evolutionary Model. W. D. HAMILTON. Nature volume 228, pages 1218–1220 (1970)Cite this article. 5368 ...
  100. [100]
    An evolutionary analysis of the relationship between spite and altruism
    May 12, 2006 · Hamilton's analysis is based on fitness effects and specifies that spiteful ... Selfish and spiteful behavior in an evolutionary model. Nature 228 ...
  101. [101]
    Spiteful Soldiers and Sex Ratio Conflict in Polyembryonic Parasitoid ...
    Spiteful behaviors are those that are harmful to both the actor and the recipient, and they represent one of the four fundamental types of social behavior ( ...
  102. [102]
    Eusociality: Origin and consequences - PMC - PubMed Central - NIH
    Sep 20, 2005 · In eusociality, an evolutionarily advanced level of colonial existence, adult colonial members belong to two or more overlapping generations, ...
  103. [103]
    Haploidploidy and the Evolution of the Social Insect - Science
    In general, but especially in eusocial ants, the ratio of investment should be biased in favor of females, and in ants it is expected to equilibrate at 1 : 3 ( ...
  104. [104]
    Reproductive Harmony via Mutual Policing by Workers in Eusocial ...
    These are part of the behavioral and discriminatory epertoire of eusocial Hymenoptera, although, except in a few cases, they have not been studied in a context ...
  105. [105]
    Lifetime monogamy and the evolution of eusociality - Journals
    Nov 12, 2009 · All evidence currently available indicates that obligatory sterile eusocial castes only arose via the association of lifetime monogamous parents and offspring.
  106. [106]
    PSR (Paternal Sex Ratio) Chromosomes: The Ultimate Selfish ...
    Because they act by completely eliminating the haploid genome of their 'hosts', PSR chromosomes are the most extreme form of selfish or parasitic DNA known. PSR ...
  107. [107]
    Chemical Communication in the Honey Bee Society - NCBI - NIH
    Pheromones allow communication among all the honey bee castes: queen–workers, workers–workers, queen–drones, and between adult bees and brood.
  108. [108]
    How does climate change affect social insects? - ScienceDirect.com
    Social insects are affected by climate change, with some traits helping them cope, but specialists will suffer. Climate change causes changes in distribution ...
  109. [109]
    Animal signals - ScienceDirect.com
    Sep 23, 2013 · The study of animal signals began in earnest with the publication in 1872 of Charles Darwin's The Expressions of the Emotions in Man and Animals.
  110. [110]
    Animal communication (article) | Ecology - Khan Academy
    Animals communicate using signals, which can include visual; auditory, or sound-based; chemical, involving pheromones; or tactile, touch-based, cues.
  111. [111]
    TPWD: Chemical Communication -- Young Naturalist - Texas.gov
    Tactile communication requires actual contact between animals and includes such gestures as a lick, nip, slap, shove, rub, or nuzzle. Coyotes, like the family ...Missing: ecology modalities
  112. [112]
    Flickering flash signals and mate recognition in the Asian firefly ...
    Feb 10, 2023 · Nocturnal fireflies sometimes use intricate bioluminescent signal systems for sexual communication. In this study, we examined flash signals ...
  113. [113]
    Monkey responses to three different alarm calls - PubMed - NIH
    Vervet monkeys give different alarm calls to different predators. Recordings of the alarms played back when predators were absent caused the monkeys to run ...
  114. [114]
    Must reliable signals always be costly? - ScienceDirect.com
    It is shown that cost-free signals can be stable even if the parameters vary, but that there must be restrictions: if costs and benefits vary uniformly over ...
  115. [115]
    Seismic communication and mate choice in wolf spiders
    We examine female choice based on isolated seismic signals to identify which aspects females use to evaluate males, and to determine whether visual and seismic ...
  116. [116]
    [PDF] Ecological Light Pollution - The Urban Wildlands Group
    Ecological light pollution alters natural light regimes, including increased illumination, glare, and sources like sky glow, streetlights, and lights on ...
  117. [117]
    Artificial nighttime lighting impacts visual ecology links between ...
    Jul 6, 2021 · In this study, we assess how different artificial light emission spectra will affect the ability of nocturnal hawkmoths to perform visually- ...
  118. [118]
    Male Photuris Fireflies Mimic Sexual Signals of Their Females' Prey
    Since Photuris females prey on males of other firefly species by mimicking their females' flashes, the Photuris males may be using their mimicry to locate ...
  119. [119]
    Firefly mate-rivals mimic their predators and vice versa - Nature
    Apr 9, 1981 · Females of Photuris versicolor and Photuris 'B' mimic the reply of P. macdermotti females thus attracting P. macdermotti males, which they eat ( ...
  120. [120]
    Mimicry and crypsis - a behavioural approach to classification
    Imitations of signals in order to satisfy the metabolic needs of the mimic, including aggressive mimicry and aggressive crypsis. 3. 3. Imitations to ...
  121. [121]
    Female Preference Predates the Evolution of the Sword in Swordtail ...
    These results suggest that the evolution of the sword in the swordtail clade was a consequence of selection arising from a preexisting bias. ... SENSORY ...
  122. [122]
    Receiver psychology and the evolution of animal signals
    It is argued that an important but neglected evolutionary force on animal signals is therefore the psychology of the signal receiver.
  123. [123]
    False alarms and information transmission in grouping animals - Gray
    Jan 18, 2023 · False alarms can be costly in terms of both the energetic costs of producing alarm behaviours as well as lost opportunity costs (e.g. abandoning ...INTRODUCTION · II. MISCLASSIFICATION OF... · III. FALSE ALARMS IN...
  124. [124]
    Detritus decorations as the extended phenotype deflect avian ...
    Jul 16, 2020 · We have demonstrated that detritus decorations constructed by C. monticola orb-web spiders deflect avian predator attacks away from the spiders.
  125. [125]
    urban birds adjust songs to noise but compromise vocal performance
    Sep 30, 2015 · These results suggest that behavioral adjustments to anthropogenic noise reduce vocal performance of songs. We conducted playback experiments to ...