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Populus alba

Populus alba, commonly known as the , silver poplar, or abele, is a fast-growing tree in the family , native to , , and . It typically reaches heights of 50 to 100 feet (15 to 30 meters) with a broad, spreading crown, featuring distinctive leaves that are triangular to heart-shaped, dark green and glossy on the upper surface, and covered with a dense white tomentum on the underside, which creates a shimmering effect in the wind. The bark is smooth and pale gray on young trees, becoming darker and deeply furrowed with age, while the tree produces catkins for and small, wind-dispersed seeds. Widely introduced to and other regions for ornamental purposes and timber production, P. alba thrives in sunny, moist soils but has become invasive in parts of the , particularly in the Midwest and Northeast, where it spreads aggressively via root suckers and can outcompete native . It is in USDA zones 3 to 8 and prefers full sun and well-drained, fertile soils, though it tolerates a range of conditions including poor soils and occasional flooding. The species is dioecious, with flowers on separate trees, and its wood is lightweight and used for , crates, and matches, while the tree also provides for . Notable for its ecological adaptability, Populus alba forms hybrids with other poplars, such as P. × canescens with P. tremula, enhancing its and invasiveness in non-native ranges. Despite its aesthetic appeal and historical cultivation in landscapes, its potential to form dense thickets has led to it being listed as a or prohibited in several states, prompting recommendations against planting it near natural areas. highlights its role in riparian zones, but management focuses on controlling its spread to protect .

Taxonomy

Classification and Synonyms

Populus alba is classified within the kingdom Plantae, phylum , class , order , family , genus , and species . This placement reflects its position as a deciduous angiosperm in the willow family, closely related to other poplars and aspens. Accepted synonyms for Populus alba include Populus alba var. pyramidalis Bunge, recognized as a heterotypic synonym. Other heterotypic synonyms listed include Populus acerifolia Lodd. ex Loudon and Populus aegyptiaca W. Baxter. The species was first formally described by in his in 1753, based on specimens from collections. The lectotype, designated by Jonsell (1993), is Herb. Burser XXIII: 19, housed at (UPS). As of the current version of (POWO), Populus alba remains an accepted species with no major taxonomic reclassifications since the 2010s, confirming its stability within the genus .

Etymology

The scientific name Populus alba derives from Latin roots central to . The genus originates from the Latin pōpulus, meaning "the people," with etymologists suggesting fanciful allusions to the tree's rapid, crowd-like proliferation in suitable habitats, though the precise connection remains uncertain. The specific alba stems directly from the Latin adjective albus (feminine form alba), signifying "," a descriptor tied to the species' distinctive pale characteristics. Common names for Populus alba reflect these Latin origins and regional linguistic adaptations. In English, it is widely known as or silver poplar, the former translating the scientific name literally and the latter emphasizing its lustrous foliage. Another historical English name, abele, entered the language in the 16th century via Dutch abeel, which traces back to Old French aubel and ultimately to Latin albellus, a of albus denoting "whitish" or "somewhat ." In some English-speaking regions, variants like whitewood appear, adapting the "white" theme to local timber terminology. The nomenclature of Populus alba was formalized by in his seminal work (1753), where he established the binomial under the Linnaean system. This description drew upon longstanding classical references, including ancient Roman authors like , who documented poplars (pōpulus) in natural histories, and Greek terms such as leukē for white-leaved variants, influencing Linnaeus's choice of epithet.

Description

Morphology

Populus alba is a that typically attains heights of 15–30 m, with a up to 2 m and a broad, spreading crown that can reach 10 m in width. The overall form is characterized by an open, rounded canopy with low, persistent branches, and the is often crooked or divided at the base. The on young is smooth and pale gray-white, providing a distinctive silvery appearance, while on mature specimens it becomes darker, rough, and deeply fissured, particularly on the lower . The leaves are alternate and exhibit heterophylly, varying between short shoots and long shoots or juvenile growth. On short shoots, they are ovate-orbicular to elliptic-ovate, measuring 4–8 cm long and 2–5 cm wide, with both surfaces covered in white tomentum. Leaves on long shoots or juvenile are larger, 4–12 cm long and up to 8 cm wide, often palmately 3–5-lobed with irregularly notched margins; the upper surface is dark green and glabrous or sparsely hairy, while the lower surface is densely white-tomentose, contributing to the 's of . Petioles are 2–6 cm long, slightly flattened, and initially tomentose. Populus alba is dioecious, with separate trees producing catkins before leaf emergence in spring. Male catkins are 3–10 cm long, bearing densely flowered spikes with 8–30 stamens per flower. Female catkins measure 5–10 cm, with ovoid ovaries that develop into narrowly conical capsules, approximately 4–6 mm long, which are glabrous or sparsely tomentose and typically 2–4-valved. These capsules split to release numerous tiny seeds, each about 1.5 mm long, enveloped in long, fine, cottony hairs that aid in wind dispersal. The root system is extensive and shallow, with dense lateral roots concentrated in the top 30–60 cm of soil and capable of extending over 20–30 m from the trunk. These roots produce abundant suckers from adventitious buds, facilitating the formation of clonal colonies and contributing to the species' vegetative propagation.

Reproduction and Growth

Populus alba exhibits both sexual and asexual reproduction, with the latter being predominant in many populations. Sexual reproduction occurs through wind-pollinated catkins that emerge in early spring, typically from March to early June, before leaf expansion. Male catkins release pollen dispersed by wind, while female catkins develop into capsules containing numerous tiny seeds coated in cottony hairs for wind dispersal. These seeds remain viable for 2–4 weeks under natural conditions and require moist substrates for germination, often along riverbanks where bare, wet soil is available. Due to the dioecious nature of the species, with separate male and female trees, and the relative rarity of males in some introduced ranges, seed production is often limited, frequently relying on hybridization with other Populus species for viable offspring. Asexual reproduction via root suckering and stump sprouting is the primary mode of , enabling the formation of extensive clonal colonies. Suckers emerge from lateral roots, sometimes up to 20–50 m from the parent trunk, leading to monotypic stands covering areas up to several hectares. This vegetative strategy allows rapid colonization of disturbed sites and contributes to the ' persistence in fragmented habitats. Juvenile growth is notably fast, with height increments of 1–2 m per year in favorable conditions during the early years, supporting quick establishment of new ramets. The lifecycle of P. alba is relatively short compared to some , with a lifespan of up to 300–400 years in optimal native conditions. productivity, including maximum accumulation and wood volume, typically occurs around 30–40 years of age, after which growth slows and susceptibility to pests increases. Phenological events align with temperate cycles: leaf-out typically begins in March–April following spring warming, marking the start of the , while autumn commences in September–October, with leaves turning yellow before to facilitate nutrient reallocation. Genetically, the species maintains high heterozygosity (observed levels around 0.50) promoted by its dioecious breeding system, which encourages when seeds are produced, though clonal dominance in many populations reduces overall .

Distribution and Habitat

Native Range

Populus alba, commonly known as , is native to a broad region across and , encompassing central and , including countries such as , , and the Balkan states; the of ; central extending to in ; and the western from to . This reflects its to diverse temperate landscapes, primarily along valleys and riparian zones where moisture is available. The species thrives in temperate to climates, with annual ranging from 400 to 1000 mm and temperature extremes from -20°C to 40°C, supporting its presence from to altitudes of up to 2000 m. These conditions allow P. alba to occupy a variety of lowland and montane environments within its native range, though it favors sites with moderate moisture and full sun exposure. Fossil records from the Pleistocene epoch indicate that Populus alba had a wider distribution during the , with evidence of its presence in additional and European sites beyond its current limits, suggesting post-glacial range contraction. Human activities, such as and changes, have further influenced the contemporary boundaries of its . As of 2025, the (POWO) database confirms the native status of P. alba across its described range, with no major contractions reported in recent assessments, underscoring its relative stability despite ongoing environmental pressures.

Introduced Ranges

Populus alba has been introduced to various regions outside its native range primarily through human-mediated planting for ornamental, , and purposes since the . In , it was first brought to the continent in 1748, with widespread cultivation following in the and for landscape enhancement and . The species has since naturalized extensively, occurring in at least 43 states across the contiguous U.S. and parts of southern , often forming dense stands in disturbed riparian and urban edge habitats. Further introductions have occurred in , where P. alba is cultivated throughout southern regions and has naturalized in low-lying, poorly drained areas such as riverbanks and roadsides, particularly in states like , , and , and in , where it has naturalized since 1904. In , it was introduced as an ornamental and timber tree, establishing populations in temperate zones and becoming naturalized along watercourses. Across , including countries like and , the tree has been planted for similar uses and has spread into naturalized populations in temperate riparian zones. In , introductions are noted in , where it is grown ornamentally and has escaped cultivation in some areas, as well as in and , supporting afforestation efforts. The primary vectors of introduction have been intentional plantings via nurseries, forestry programs, and landscape trade, dating back to the 1700s for timber production and soil stabilization. Once established, natural spread occurs through vegetative means, including prolific root suckering that forms clonal thickets, and to a lesser extent via wind-dispersed seeds from female trees, facilitating colonization of new sites along floodplains and disturbed landscapes. Today, P. alba occupies significant extents in introduced landscapes, such as urban parks, rural windbreaks, and wild riparian corridors, reflecting its adaptability to temperate climates beyond its Eurasian origins.

Ecology

Habitat Preferences

Populus alba thrives primarily in alluvial and sandy-loam soils, particularly those with high sand content exceeding 96% in some regions, and it demonstrates notable adaptability to nutrient-poor and low water-holding capacity substrates. It tolerates a wide range from 5.0 to 8.0, encompassing acidic to alkaline conditions, and can endure poor drainage as well as levels up to approximately 5 dS/m, equivalent to around 3,200 mg/L of salts at shallow depths. Optimal growth occurs in moist soils with 16% to 34% moisture content, though it performs adequately in loamy sands to deep loams. As a riparian and specialist, P. alba exhibits strong , surviving up to 61–69 days of inundation with 80% viability, but its diminishes beyond 100 days, and mature s become more sensitive to prolonged . It requires moderate to high annual , typically exceeding 600 mm, with suitable regimes ranging from 300–1,000 mm in bimodal or uniform patterns, supporting its preference for sites with consistent water availability near watercourses. This species is hardy across USDA zones 3–9, enduring winter temperatures as low as -40°C (-40°F) and summer heat with daytime optima of 25–35°C (77–95°F), while withstanding periodic winter flooding and hot, dry summers in continental climates. It commonly occupies dynamic landforms such as riverbanks, lake margins, bars, coastal dunes, and sandy ridges, favoring open, sunny, and disturbed habitats.

Ecological Interactions

Populus alba is primarily wind-pollinated, with catkins releasing in early to facilitate cross-pollination among dioecious individuals. While play a minor role in pollen transfer, the relies mainly on anemophily for . Seed dispersal occurs predominantly via wind, as the small, tufted capsules release lightweight seeds that can travel long distances, often aided by water in riparian zones. The roots of Populus alba form symbiotic associations with mycorrhizal fungi, including both arbuscular and ectomycorrhizal types, which enhance nutrient uptake, particularly and , from the soil. These fungi extend the system's absorptive capacity, improving plant growth in nutrient-poor environments. Although free-living -fixing can associate with roots, P. alba does not form actinorhizal symbioses typical of other pioneer plants. Populus alba is susceptible to herbivory and pest damage from various insects and mammals. Aphids, such as those in the genus Chaitophorus, feed on sap from leaves and stems, potentially causing curling and reduced vigor. Leaf miners, including larvae of moths and flies, create serpentine trails within foliage, defoliating young trees. Fungal pathogens like Cytospora spp. cause cankers that girdle branches and trunks, leading to dieback. Mammalian herbivores, including white-tailed deer and rabbits, browse twigs and foliage of saplings, occasionally impacting regeneration. As a , Populus alba plays a key role in ecosystem dynamics by colonizing disturbed sites and stabilizing soils through its extensive , which binds riparian and sediments. It provides habitat and food resources for numerous species, supporting in early-successional communities. Additionally, mature stands contribute to , aiding in atmospheric CO₂ mitigation.

Conservation and Invasiveness

Conservation Status

Populus alba is classified as on the IUCN European Red List of Trees, based on a 2017 assessment that found no evidence of significant global population declines across its native range. This status reflects the ' wide distribution and adaptability, with stable overall populations despite localized pressures. NatureServe similarly ranks it as Globally Secure (G5) in its native Eurasian range, indicating low risk of extinction at a global scale, with the last review confirming its persistence in diverse habitats. Regionally, conservation concerns vary. In parts of , populations face vulnerability from in riparian zones, which degrades floodplain forests and limits regeneration. Within the , P. alba is integral to protected riparian gallery forests listed under Annex I of the EU (habitat code 92A0: Salix alba and Populus alba galleries), requiring favorable conservation status and to preserve these ecosystems. No major updates to its IUCN status have occurred as of 2025, maintaining the Least Concern designation. Population trends show no net global decline, but fragmentation is evident in the , where habitat loss has isolated stands and reduced genetic connectivity. Key threats include river damming and channelization, which disrupt natural flooding regimes essential for establishment, and , which encroaches on alluvial floodplains. exacerbates these issues, with 2024 modeling for European temperate trees projecting distributional shifts for P. alba, potentially altering up to 20% of its suitable range under moderate emissions scenarios. In introduced regions, its invasive tendencies contrast with native stability, though management focuses elsewhere.

Invasive Potential and Management

Populus alba exhibits high invasive potential in several non-native regions, including , , and parts of the . In , it forms dense thickets that threaten riparian vegetation and disturbed wetlands by displacing through aggressive clonal growth. In , it is classified as a Category 2 weed under the National Environmental Management: Biodiversity Act, contributing to widespread ecological disruption in riparian zones. Within the U.S., it is considered invasive in due to its ability to establish dense stands that outcompete native flora, and it is considered invasive across and other states. These invasions often result in the formation of monocultures that suppress diversity and alter local ecosystems. The species spreads primarily through clonal suckering from extensive root systems and wind-dispersed produced in large quantities, enabling rapid of disturbed sites. suckers can form expansive clonal patches, while facilitate long-distance dispersal, particularly in riparian and open habitats. Recent studies utilizing imagery and classification have mapped its expansion in mountainous ecosystems, highlighting its increasing coverage in vulnerable areas. Invasive P. alba impacts by consuming substantial , reducing availability for native riparian and potentially exacerbating conditions in invaded areas. It also diminishes by outcompeting native , including willows (Salix spp.), through superior and shading effects that limit light and nutrient access. These ecological shifts lead to economic costs, such as failures in native vegetation-based efforts where P. alba displaces stabilizing like willows, increasing vulnerability to loss and flood damage. Management strategies for P. alba include mechanical removal of seedlings and young plants to prevent resprouting, though repeated efforts are necessary due to vigorous suckering. Herbicides such as , applied as foliar sprays at 2% solutions, effectively control seedlings and small trees when timed for active growth periods. Biological controls remain under study, with ongoing research exploring potential agents like fungi or insects, though no widely implemented options exist yet. In the , 2025 risk assessments by the evaluate phytosanitary measures for imports of P. alba plants to mitigate introduction risks.

Cultivation and Uses

Cultivation Practices

Populus alba is commonly propagated through vegetative means, particularly using stem cuttings, which allow for rapid clonal reproduction. or semi-hardwood cuttings taken during winter are planted directly in outdoor beds or for initial rooting, with typically developing within 2 to 4 weeks under favorable conditions. Seeds provide an alternative method, requiring no due to their short viability; fresh seeds germinate within 12 to 48 hours at temperatures of 84–89°F (29–32°C), with pre-soaking in a 2 M solution for 30 minutes improving rates to over 85%. techniques, including from shoot tips, enable mass production of clones, yielding up to 90% rooted plantlets that acclimatize successfully in sand-peat mixtures under conditions. Optimal site selection for cultivation emphasizes full sun exposure, as Populus alba is light-demanding and performs best with at least 6 hours of direct sunlight daily. It prefers moist, fertile alluvial or loamy soils but adapts to a wide range including sandy, clay, or even saline types, provided drainage prevents waterlogging. In plantation settings, spacing of 3–5 meters between trees facilitates growth and access, while supplemental irrigation is essential in arid regions to sustain soil moisture during establishment and dry periods. Ongoing maintenance focuses on structural integrity and health, with recommended during to remove lower branches, promote a central leader, and reduce epicormic shoots, thereby enhancing form and wind resistance. Regular monitoring for pests such as scales, borers, and canker-causing is crucial, with integrated including dormant-season treatments to minimize impacts in short-rotation systems. For production, short rotations typically span 2–10 years, depending on coppice and use, allowing trees to reach harvestable size while balancing yield and site recovery. Recent research highlights advances in fast-growing variants and hybrids of Populus alba for , including selections tolerant to and salinity for climate adaptation, as noted in EUFORGEN guidelines updated through 2020. USDA-supported studies from 2020–2023 on poplar systems emphasize these traits for and sustainable biomass, with ongoing genomic work identifying climate-resilient clones.

Commercial and Ornamental Uses

Populus alba, commonly known as , provides lightweight that is primarily utilized in the production of for , as well as for crates, pallets, and matches due to its straight grain and ease of processing. The wood is also employed in the fabrication of particleboard, where its fibrous structure contributes to panel and cost-effectiveness in composite materials. With an average air-dry density ranging from 380 to 530 kg/m³, the species yields a content that supports efficient pulping, typically around 40-50% of dry wood mass, making it a viable resource for industrial applications in regions with established processing facilities. In ornamental contexts, Populus alba is widely planted for its striking aesthetic appeal, featuring leaves with a silvery-white underside that creates a shimmering effect in breezes, often lining , parks, and spaces for visual enhancement. The serves as an effective shade provider and , particularly in temperate landscapes, where its rapid growth and tolerance to exposed conditions allow it to form protective screens along roadsides and boundaries. Examples include its use in avenue plantings in the and coastal areas for both functional shelter and decorative purposes. Beyond wood products, the bark of Populus alba has been traditionally used to extract compounds for , while its leaves serve as for in certain arid or regions, providing a nutritious rich in vitamins during scarcity. Recent studies have highlighted the properties of leaf extracts, with 2024 research demonstrating inhibitory effects against and potential as alternatives to synthetic antibiotics through compound activity. In the , particularly the U.S. Southwest, Populus alba is applied in along riverbanks and disturbed sites, though its planting is restricted in some states due to invasive tendencies and competition with native vegetation. Globally, poplar plantations, including those of Populus alba and hybrids, span over 20 million hectares as of 2024, underscoring the species' economic role in and systems.

Hybridization

Known Hybrids

Populus alba readily hybridizes with other species in the genus Populus, particularly those in section Populus, resulting in both natural and cultivated hybrids. The most prominent natural hybrid is Populus × canescens (Aiton) Sm., commonly known as grey poplar, formed from P. alba and P. tremula L. (European aspen). This hybrid occurs spontaneously in zones of sympatry across Europe, where the parent species overlap in riparian and floodplain habitats, and is characterized by its vigorous growth and intermediate morphology. In , natural hybrids involving P. alba—introduced from —have been documented primarily east of the . These include Populus × rouleauiana Boivin (P. alba × P. grandidentata Michx., bigtooth aspen), a rare form known from , and hybrids with P. tremuloides Michx. (quaking aspen), which arise in areas of distributional overlap and exhibit variable leaf and bark traits. Such spontaneous hybridization contributes to but can complicate species identification in mixed stands. Cultivated hybrids of P. alba have been developed intentionally since the early through programs aimed at enhancing timber production, disease resistance, and growth rates via hybrid vigor. Notable examples include the interspecific cross P. alba × P. grandidentata, pursued in the United States for improved qualities, and European selections like hybrid poplar '717' (P. tremula × P. alba), originating from 1960s programs at the for Agricultural (INRA) for and shelterbelt applications. In , hybrids such as 84K (P. alba × P. tremula var. glandulosa), developed in and widely planted in northern , demonstrate rapid growth suited to . These artificial crosses build on spontaneous origins but are propagated clonally for commercial consistency. Recent genetic studies, including those from 2025, have utilized DNA markers such as microsatellites and whole-genome sequencing to confirm identities and parentage, revealing complex patterns and in P. alba-derived taxa. For instance, analyses of P. alba × P. glandulosa have identified key genetic contributions from both parents, supporting the recognition of multiple hybrid forms across and , though exact counts vary by taxonomic treatment.

Hybrid Characteristics

Hybrids involving Populus alba typically display intermediate morphological characteristics that blend traits from both parental species, such as leaf shape and pubescence. For example, in P. × canescens (P. alba × P. tremula), the leaves are triangular-ovate with reduced white tomentum on the underside compared to the densely tomentose leaves of pure P. alba, resulting in a less silvery appearance overall. These hybrids often attain greater stature than their parents, with P. × canescens capable of reaching heights up to 40 m under optimal conditions. Growth rates in P. alba hybrids are notably accelerated, exceeding parental rates by approximately 20–30%; for instance, P. alba × P. grandidentata achieves heights of 5.4 m at five years old, compared to 4.3 m for P. alba. In terms of growth and reproduction, P. alba hybrids demonstrate enhanced accumulation, often yielding 20–50% more per than parental due to hybrid vigor. Some F1-generation hybrids exhibit partial sterility, with reduced viability and abortion rates exceeding those of parents, limiting further natural hybridization beyond the first generation. Enhanced flood tolerance is a key trait, allowing survival under prolonged submersion (up to 69 days with 80% viability) that exceeds the tolerance of less adapted parents like P. tremula. Ecologically, P. alba hybrids offer broader adaptability to varied soil types and climates than their progenitors, thriving in riparian zones and marginal lands where pure P. alba may struggle. They are particularly valued for , with interspecific hybrids like P. alba × P. glandulosa showing high accumulation of such as (up to 1.9 mg per plant) while maintaining growth under stress. Studies from 2020–2025 highlight improved in these hybrids, including reduced to like Anoplophora glabripennis through genetic enhancements, outperforming parental lines in field trials. These traits make P. alba hybrids preferable for commercial plantations, especially for production, where their rapid accrual supports short-rotation cycles. For example, P. alba × P. tremula var. glandulosa (clone 84K) is widely planted in northern for , timber, and pulp due to its adaptability and yield advantages.

History and Cultural Significance

Historical Cultivation

Populus alba has been cultivated since ancient times in the Mediterranean region, where it was valued for its timber and broad canopy providing shade in orchards and public spaces, contributing to its widespread planting across . European colonists introduced the species to the Americas, with records indicating its arrival in the United States around 1784, including early plantings in for ornamental and utilitarian purposes such as shade and . By the late , it had begun naturalizing in North American riparian zones. In the 19th and 20th centuries, industrial breeding programs emerged in the United States and to improve P. alba for timber production, with controlled hybridizations in the early 20th century to enhance growth rates and disease resistance. Following , large-scale plantations were established in and to meet postwar demands for in paper and packaging industries, leveraging the tree's fast growth and soft wood. These efforts expanded P. alba's role in commercial forestry, with hybrids like P. × canescens integrated into breeding for higher yields. From 2020 to 2025, cultivation of P. alba has shifted toward sustainable , as highlighted in International Poplar Commission () reports emphasizing its use in windbreaks, , and integrated crop systems to combat and . initiatives, including the 27th session in 2024, promote diverse planting strategies for environmental resilience, with P. alba featured in programs like China's Three North Shelterbelt for and . This evolution reflects a broader focus on ecological benefits over intensive monocultures.

Mythological and Artistic References

In Greco-Roman mythology, the white poplar (Populus alba) held sacred status, particularly associated with , who crowned himself with its branches after defeating the fire-breathing giant near the in . This act consecrated the tree to the hero, symbolizing victory and triumph over adversity. Additionally, the nymph Leuce, abducted by and transformed upon her death into a white poplar in the , linked the tree to themes of eternal memory and the afterlife, underscoring its role as a bridge between the mortal world and the underworld. In Virgil's , the white poplar appears in the underworld landscape, where and the pass a grove of these trees en route to , evoking the realm's liminal and shadowy essence. Artistically, Populus alba wood has been prized for its fine grain and workability, featuring prominently in masterpieces. Donatello's Penitent Magdalene (c. 1453–1455), a life-sized polychromed wooden depicting the saint's ascetic transformation, was carved from a single trunk of , emphasizing the material's ability to convey emotional depth and spiritual gauntness. Similarly, Leonardo da Vinci's (c. 1503–1506) was painted on a panel of Populus alba, chosen for its stability and prevalence in workshops, allowing the subtle layering of glazes that define the work's enigmatic quality. In and , the embodies , drawing from its ability to thrive in diverse conditions like floods and droughts, as seen in ancient tales of that highlight adaptability and renewal. This persists in modern environmental contexts, where the tree represents endurance amid ; for instance, a of myths interprets Leuce's as a lesson in fragility and resilience relevant to contemporary narratives. Poplars, including Populus alba, were valued in Persian-influenced historical designs for providing shade in arid landscapes, integrated alongside willows and planes for paradisiacal oases. Recent artistic projects, such as the Aula Verde in —comprising Populus alba trees arranged to symbolize environmental connectivity—further link the species to , fostering dialogue on through interdisciplinary art and science.