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Shrubland
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Shrubland
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Low shrubland in Hawaii
Scrub vegetation with cactus in Webb County in south Texas
Mediterranean shrubland in Sardinia, Italy

Shrubland, scrubland, scrub, brush, or bush is a plant community characterized by vegetation dominated by shrubs, often also including grasses, herbs, and geophytes. Shrubland may either occur naturally or be the result of human activity. It may be the mature vegetation type in a particular region and remain stable over time, or it may be a transitional community that occurs temporarily as the result of a disturbance, such as fire. A stable state may be maintained by regular natural disturbance such as fire or browsing.

Shrubland may be unsuitable for human habitation because of the danger of fire. The term was coined in 1903.[1]

Shrubland species generally show a wide range of adaptations to fire, such as heavy seed production, lignotubers, and fire-induced germination.[2]

Botanical structural form

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In botany and ecology a shrub is defined as a much-branched woody plant less than 8 m high, usually with many stems. Tall shrubs are mostly 2–8 m high, small shrubs 1–2 m high and subshrubs less than 1 m high.[3]

There is a descriptive system widely adopted in Australia to describe different types of vegetation is based on structural characteristics based on plant life-form, as well as the height and foliage cover of the tallest stratum or dominant species.[4]

Shrubland in Prince Edward County, Ontario.

For shrubs that are 2–8 metres (6.6–26.2 ft) high, the following structural forms are categorized:

  • dense foliage cover (70–100%) — closed-shrubs
  • mid-dense foliage cover (30–70%) — open-shrubs
  • sparse foliage cover (10–30%) — tall shrubland
  • very sparse foliage cover (<10%) — tall open shrubland

For shrubs less than 2 metres (6.6 ft) high, the following structural forms are categorized:

  • dense foliage cover (70–100%) — closed-heath or closed low shrubland—(North America)
  • mid-dense foliage cover (30–70%) — open-heath or mid-dense low shrubland—(North America)
  • sparse foliage cover (10–30%) — low shrubland
  • very sparse foliage cover (<10%) — low open shrubland

Biome plant group

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Mixed chaparral habitat in the Santa Monica Mountains National Recreation Area
Fynbos in South Africa

Similarly, shrubland is a category that is used to describe a type of biome plant group. In this context, shrublands are dense thickets of evergreen sclerophyll shrubs and small trees,[5] called:

In some places, shrubland is the mature vegetation type. In other places, it is the result of degradation of former forest or woodland by logging or overgrazing, or disturbance by major fires.[citation needed]

A number of World Wildlife Fund biomes are characterized as shrublands, including the following:[6][7]

Desert scrublands

The Nullarbor Plain in Australia

Xeric or desert scrublands occur in the world's deserts and xeric shrublands ecoregions or in fast-draining sandy soils in more humid regions. These scrublands are characterized by plants with adaptations to the dry climate, which include small leaves to limit water loss, thorns to protect them from grazing animals, succulent leaves or stems, storage organs to store water, and long taproots to reach groundwater.[6]

Mediterranean scrublands

Mediterranean scrublands occur naturally in the Mediterranean scrub biome, located in the five Mediterranean climate regions of the world. Scrublands are most common near the seacoast and have often adapted to the wind and salt air of the ocean. Low, soft-leaved scrublands around the Mediterranean Basin are known as garrigue in France, phrygana in Greece, tomillares in Spain, and batha in Israel. Northern coastal scrub and coastal sage scrub occur along the California coast, strandveld in the Western Cape of South Africa, coastal matorral in central Chile, and sand-heath and kwongan in Southwest Australia.[7]

Interior scrublands

Interior scrublands occur naturally in semi-arid areas with nutrient-poor soils, such as on the matas of Portugal, which are underlain by Cambrian and Silurian schists. Florida scrub is another example of interior scrublands.

Dwarf shrubs

Moorland on Kilimanjaro

Some vegetation types are formed of dwarf-shrubs, low-growing or creeping shrubs. They include the maquis and the garrigues of Mediterranean climates and the acid-loving dwarf shrubs of heathland and moorland.

See also

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Notes and references

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Shrubland

View on Grokipedia
from Grokipedia
Shrubland is a terrestrial characterized by dominated by woody , typically under 5 meters in height, with shrub canopy cover exceeding 20% and often interspersed with grasses, herbs, and occasional small trees. These ecosystems occur primarily in semi-arid to Mediterranean-type climates between 30° and 40° latitudes north and south, including regions like the Mediterranean Basin, , , southwestern Australia, and the Cape region of . in shrublands features hot, dry summers with temperatures reaching up to 38°C and mild, wetter winters with average lows around 9°C, receiving 200–1,000 mm of annual precipitation that is often unpredictable and concentrated in winter months. Dominant includes drought- and fire-adapted species such as chamise, , , and aromatic herbs like sage and , which possess small, waxy, or needle-like leaves to conserve water and resprout after fires. Shrublands serve as critical transitional habitats between grasslands and forests, supporting high and essential services, including wildlife habitats for birds, mammals, and , as well as and . Common types include in Mediterranean climates, sagebrush steppe in North American interiors, and fynbos in , each shaped by local stressors like aridity, nutrient-poor soils, and frequent wildfires that maintain shrub dominance. These biomes face threats from , altered fire regimes, and , which challenge their persistence and ecological integrity.

Definition and Classification

Botanical Definition

Shrublands are plant communities dominated by shrubs, which are defined botanically as woody plants that typically grow to heights of less than 6-8 meters, featuring multiple stems arising from the base rather than a single central trunk. These plants exhibit persistent woody stems above ground, distinguishing them from herbaceous vegetation, and their multi-stemmed architecture allows for a bushy growth form adapted to various environmental stresses. Unlike trees, shrubs lack the vertical dominance and singular bole structure that enable canopy closure at greater heights, positioning them as intermediate between tall forests and low-lying grasslands. In botanical terms, shrublands are characterized by where the layer forms the dominant , with shrubs comprising more than 50% of the total vegetative cover and exhibiting heights generally ranging from 0.5 to 5 meters. The canopy cover in these communities typically falls between 10% and 60%, creating an open to moderately dense structure that differentiates shrublands from denser forests—where trees exceed 8 meters and achieve over 10% cover—and from grasslands, which are primarily composed of non-woody, herbaceous plants without significant woody elements. This structural dominance by shrubs ensures that the community lacks a continuous overstory of taller trees, emphasizing horizontal spread over vertical growth. Shrubs in these ecosystems display diverse structural forms, including sclerophyllous types with thick, leathery leaves for water retention, as well as evergreen or deciduous variants depending on regional adaptations. For instance, in chaparral shrublands, species such as chamise (Adenostoma fasciculatum) and manzanita (Arctostaphylos spp.) feature evergreen, sclerophyllous foliage that minimizes transpiration in dry conditions, exemplifying how botanical traits like leaf morphology contribute to the overall resilience of the shrubland structure. These forms collectively define the botanical identity of shrublands, prioritizing multi-stemmed woody persistence over arboreal height or graminoid flexibility.

Ecological Classification

Shrublands are recognized as a major group in global ecological frameworks, positioned as transitional ecosystems between forests and more open formations such as grasslands and deserts. In the World Wildlife Fund's (WWF) Terrestrial Ecoregions of the World classification, shrublands are integrated into several categories, including ; ; ; and , reflecting their intermediate role in moisture and vegetation density gradients. Similarly, the system, a bioclimatic classification based on annual biotemperature, precipitation, and potential evapotranspiration, delineates shrublands within dry to subhumid zones such as subtropical /shrubland and tropical shrubland, where they occupy niches between moist forest zones and arid deserts. Sub-biome categories of shrublands are delineated based on climatic and adaptive characteristics, encompassing temperate shrublands in cooler, seasonal climates; Mediterranean shrublands adapted to summer and winter rain; montane shrublands at higher elevations with alpine influences; and arid shrublands in low-precipitation environments. These categories emphasize ecological adaptations to specific environmental stressors, such as extremes in temperate zones or in arid ones, allowing for a hierarchical understanding within broader schemes. Shrublands often fulfill functional roles as fire-prone systems, where frequent low-intensity fires maintain structure and promote regeneration through adaptations like resprouting and fire-stimulated seed germination, particularly in western ecosystems. They also serve as adapters to nutrient-poor soils, with evolved to recycle limited resources efficiently in oligotrophic conditions. In , shrublands frequently represent seral stages following disturbances like fire or , acting as intermediate communities that transition toward forests or persist as stable states in persistent shrublands. Historical classifications of shrublands have emphasized —the structural and growth-form attributes—and floristics—the composition—to define types. Pierre Dansereau's 1951 physiognomic scheme classified , including shrublands, using symbols for leaf size, shape, and overall structure to enable global comparisons and mapping, prioritizing external form over identity. Heinz Ellenberg, in collaboration with Dieter Mueller-Dombois, advanced integrated approaches in their 1974 work, combining physiognomic structure with floristic elements to analyze dynamics and environmental correlations, influencing modern ecological delineations of shrubland communities.

Physical and Environmental Characteristics

Vegetation Structure

Shrubland vegetation often displays a multi-layered architecture, with an understory composed of herbaceous plants and grasses, a prominent mid-story of shrubs forming the primary canopy, and occasional emergent trees that do not dominate the overall structure. This layering supports diverse microhabitats while maintaining an open aspect suited to the prevailing environmental constraints. The shrub layer typically achieves an average canopy closure of 20-50%, allowing significant light penetration to the and contributing to the ecosystem's resilience against disturbances like . Key adaptations in shrubland plants enhance survival in water-limited conditions, including extensive systems such as deep taproots that access subsurface moisture and lateral that exploit shallow runoff. Leaf traits further minimize , featuring small, thick, or waxy surfaces that reduce surface area and create a hydrophobic barrier to loss. These morphological features are prevalent across shrubland dominants, enabling persistence in arid and semi-arid regimes. Phenological patterns vary by shrub type, with deciduous species exhibiting seasonal leafing and shedding to conserve resources during dry periods, contrasted by forms that retain foliage year-round for opportunistic when is available. Growth rates in shrublands are generally slow, constrained by and limitations, resulting in gradual accumulation over years or decades. Structural metrics highlight the compact nature of shrubland , with shrub heights often distributed in histograms peaking between 0.5 and 3 meters, reflecting to and pressures. Biomass allocation prioritizes above-ground components, with 60-80% directed to stems and leaves for and , while roots receive a substantial but secondary share to balance acquisition. These patterns underscore the of use in resource-poor environments.

Soil and Climate Influences

Shrubland soils are typically shallow, rocky, or sandy, exhibiting low fertility due to limited and nutrient availability, with values ranging from 5.5 to 8.1 across various regions. These soils often feature poor retention but high drainage rates, which prevent waterlogging while promoting rapid and susceptibility in disturbed areas. Nutrient cycling in these nutrient-poor environments relies heavily on symbiotic relationships with mycorrhizal fungi, which enhance and uptake for shrubs, thereby sustaining productivity in low-fertility conditions. Climatic conditions in shrublands are predominantly semi-arid to subhumid, characterized by annual of 200 to 1,000 millimeters, often concentrated in seasonal patterns with prolonged droughts. Temperatures can fluctuate widely from -40°C to 50°C annually, with hot, dry summers and cooler winters that can include frost. In Mediterranean shrublands, winter rains play a critical role by providing the bulk of annual moisture during the , supporting establishment before the onset of summer . These edaphic and climatic factors interact to maintain shrubland ecosystems by limiting growth through chronic water deficits, where rates commonly exceed , inducing persistent water stress that favors low-stature shrubs over taller . Seasonal droughts further constrain deep-rooted development, while disturbances like and erode stability, removing protective cover and accelerating loss, yet also promoting shrub regeneration in adapted species.

Types and Global Variations

Temperate Shrublands

Temperate shrublands consist of ecosystems dominated by low to medium-height woody shrubs, often or mixed with , adapted to continental climates featuring cold winters and moderate summers with pronounced seasonal variations. These regions typically receive 250-900 mm of annual , supporting a layer where shrubs form 25-80% cover, interspersed with grasses and forbs, while trees remain sparse due to frost, , or historical disturbances. Unlike warmer shrublands, temperate variants emphasize resilience to freezing temperatures and periodic snow cover, fostering open, patchy landscapes that transition between grasslands and forests. Prominent examples include the North American , spanning the with dominant Artemisia tridentata ( family) on deep, well-drained soils, enduring cold snaps down to -30°C; European heathlands, widespread in the UK and Scandinavia, characterized by Calluna vulgaris and Erica species ( family) on nutrient-poor, acidic substrates; the shrubby fringes of the Siberian , where deciduous dwarf shrubs like Betula and Salix mark ecotones between boreal forests and ; and Appalachian shrub bogs in the eastern U.S., featuring ericaceous thickets such as and Kalmia in saturated, peat-forming depressions. These systems collectively reflect post-glacial recolonization patterns where retreating ice sheets circa 10,000-12,000 years ago exposed mineral soils for pioneer shrub establishment. Shrubs in these ecosystems display key adaptations including frost resistance via physiological mechanisms like of tissues and insulating bark, alongside seasonal dormancy during winter to conserve energy amid subzero conditions and short growing seasons of 100-200 frost-free days. Dominant families such as (heaths and bog shrubs) and (sagebrushes) prevail due to their sclerophyllous leaves and mycorrhizal associations that enhance uptake in oligotrophic soils. Ecologically, temperate shrublands contribute to landscape stability, particularly post-disturbance, by rapidly recolonizing burned or logged areas through resprouting and seed banks, thereby binding soils with extensive fibrous and reducing rates in recovery phases. Primary productivity in temperate shrublands averages 200-500 g/m²/year of aboveground , varying with moisture availability—higher in mesic heathlands (up to 600 g/m²/year) and lower in arid steppes—sustained by belowground allocations that exceed 70% of total production for and tolerance. This moderate output underscores their role as transitional habitats, buffering against extremes while maintaining stocks through slow in cool conditions.

Mediterranean and Arid Shrublands

Mediterranean and arid shrublands are characterized by dense stands of sclerophyllous shrubs adapted to hot, dry summers and mild, wet winters, forming a distinct type in regions with a Mediterranean-type . These ecosystems typically receive annual rainfall between 250 and 750 millimeters, concentrated in winter, which supports drought-resistant on often nutrient-poor, sandy or rocky soils. Unlike temperate shrublands, which feature more forms in cooler conditions, Mediterranean shrublands emphasize persistent foliage to maximize during brief wet periods. Prominent examples include the chaparral of California, where shrubs like chamise (Adenostoma fasciculatum) and manzanita (Arctostaphylos spp.) dominate coastal slopes; the matorral of central Chile, featuring sclerophyllous shrubs such as Lithraea caustica and Kageneckia oblonga in coastal and Andean foothills; the mallee shrublands of southern and western Australia, featuring multi-stemmed eucalypts such as Eucalyptus dumosa in semi-arid woodlands; and the fynbos of South Africa's Cape region, a proteoid shrubland with fine-leaved restioids, ericoids, and proteas. These formations occur in five global hotspots—around the Mediterranean Basin, California, central Chile, southwestern Australia, and the Cape Floristic Region—each shaped by similar climatic patterns but with unique floral assemblages. Plants in these shrublands exhibit specialized adaptations to frequent fires and prolonged droughts, including thick, leathery leaves that reduce water loss, lignotubers for post-fire resprouting, and serotinous cones or fruits that release seeds only after heat exposure. High concentrations of volatile oils in foliage, such as in shrubs, enhance flammability, promoting a fire-dependent life cycle where burns every 20-50 years clear competitors and trigger regeneration. Drought tolerance is further aided by deep root systems and seasonal leaf shedding in some species, allowing survival in summer . In more arid variations, such as the scrub of the and northwestern , succulent shrubs like (Simmondsia chinensis) and bursage (Ambrosia deltoidea) prevail alongside cacti, enduring even lower rainfall of 100-300 millimeters with water-storing tissues. Biodiversity reaches exceptional levels in the , harboring over 9,000 species, more than half endemic, driven by edaphic diversity and fire regimes. These shrublands originated during Tertiary climate shifts in the epoch (approximately 23-5 million years ago), when global cooling and tectonic uplift established summer-dry regimes, and they collectively cover about 3 million square kilometers worldwide.

Biodiversity and Ecology

Plant Diversity

Shrublands exhibit notable plant diversity, characterized by dominant families such as , , and , which play key roles in ecosystem structure and function across various regions. In Australian kwongan shrublands, genera like , , and are prevalent, comprising a significant portion of the on nutrient-poor soils. , particularly species, dominate in , contributing to post-fire recovery through resprouting abilities. is widespread globally, with nitrogen-fixing species enhancing in arid and semi-arid shrublands. Endemic is particularly high in biodiversity hotspots; for instance, the shrublands of South Africa's host over 9,000 vascular plant species, with approximately 70% , driven by unique adaptations to fire-prone, low-nutrient environments. Plant adaptations in shrublands promote survival in harsh conditions, including for resource competition, for nutrient acquisition, and diverse mechanisms. Allelopathy, where plants release chemicals to inhibit competitors, is evident in species like Ceratiola ericoides in shrublands, where leaf litter suppresses growth to maintain dominance. shrubs from , such as those in arid environments, form symbiotic relationships with , improving soil nitrogen availability and supporting community resilience. strategies vary, with many shrubs relying on for targeted transfer, though some grasses and forbs within shrublands use dispersal to ensure in open, windy habitats. Life history strategies often include short-lived that rapidly colonize post-disturbance sites, facilitating succession in fire-adapted systems. Diversity metrics highlight shrublands' variability, with density typically ranging from 20 to 100 per 0.1 , though hotspots in Mediterranean climates can exceed 100 due to fine-scale heterogeneity. For example, California chaparral averages around 50 per 0.1 in early successional stages, reflecting high post-fire richness. These patterns stem from evolutionary radiations following the , where climatic stability and recurrent fires drove in regions like the Mediterranean Basin and southwestern , leading to adaptive traits such as serotiny and resprouting. Rare and threatened underscore conservation needs, with studies revealing vulnerabilities in fragmented habitats. In , Banksia species like B. cuneata exhibit low due to historical declines, prompting management to preserve evolutionary potential across populations. Similarly, California's Ceanothus ferrisiae, a federally endangered , shows limited , with seed collections aimed at capturing remaining variation to support restoration efforts. These examples highlight how amplifies risks in shrublands.

Fauna and Interactions

Shrublands support diverse faunal communities adapted to sparse cover, , and periodic disturbances, with animals playing key roles in nutrient cycling and . Small mammals, birds, reptiles, and form where herbivores consume shrub foliage and seeds, while predators regulate populations through dynamic interactions. These ecosystems feature relatively low faunal compared to forests, but high specialization in and strategies enables coexistence with dominant species that provide limited but critical cover and food resources. Mammalian fauna in shrublands often includes small herbivores well-suited to open, low-cover environments. Species such as kangaroo rats (Dipodomys spp.) in North American desert shrublands exhibit bipedal locomotion for efficient seed harvesting and burrowing behaviors to escape predators and conserve water, allowing them to thrive in areas with sparse perennial vegetation. Similarly, black-tailed jackrabbits (Lepus californicus) and desert cottontails (Sylvilagus audubonii) graze on shrub leaves and forbs, using their speed and cryptic coloration for protection amid limited hiding spots. These adaptations minimize energy expenditure in resource-poor habitats, where populations fluctuate with seasonal rainfall and shrub productivity. Birds contribute significantly to shrubland dynamics through foraging and dispersal services. Ground-dwelling species like (Callipepla gambelii) in southwestern U.S. arid shrublands consume seeds from grasses and shrubs, inadvertently dispersing them via and promoting plant regeneration in patchy landscapes. Corvids such as the western scrub-jay (Aphelocoma californica) in shrublands cache acorns and other seeds from oaks and pines, with uneaten stores fostering shrub establishment and maintaining in fire-prone areas. These birds often form coveys or flocks that exploit seasonal flushes of shrub fruits, linking faunal mobility to vegetation cycles. Invertebrates and reptiles enhance and reproductive processes in shrublands. Ant communities exhibit high , particularly in arid types, where genera like Pogonomyrmex and construct extensive nests that aerate soil and redistribute nutrients, improving shrub root access to water in compacted substrates. Reptiles, including the (Sceloporus occidentalis) in shrublands, bask on rocks and forage for amid low shrubs, with specialized kidneys enabling water retention in dry conditions. networks involve native bees (e.g., species in and ) that visit shrub flowers like those in and , forming specialized interactions that ensure cross-pollination despite sparse floral resources; these networks show modular structure, with bees prioritizing drought-tolerant shrubs during peak blooming. Trophic interactions in shrublands revolve around shrubs as primary producers, supporting layered food webs where herbivory by small mammals and consumes 10-20% of annual foliage and in many systems, influencing shrub architecture and regrowth. Predator-prey dynamics intensify post-, as reduced cover exposes herbivores like to increased predation by foxes and raptors, temporarily shifting abundances and accelerating nutrient turnover through carcass decomposition. These interactions maintain balance, with apex predators such as coyotes (Canis latrans) controlling numbers, preventing that could degrade sparse shrub cover. events disrupt webs short-term but enhance long-term resilience by regenerating resources that sustain diverse trophic levels. Endemism highlights shrublands' role in conserving unique fauna tied to regional conditions. In Australian mallee and heath shrublands, the quokka (Setonix brachyurus) is a near-endemic that browses on shrubs and grasses, with populations restricted to southwestern habitats where dense provides refuge; though largely sedentary, local movements track seasonal shrub fruiting. South Africa's Succulent shrublands host endemic birds like the Karoo lark (Certhilauda albescens) and Karoo korhaan (Eupodotis vigorsii), which forage on seeds and insects amid succulent shrubs; these species exhibit nomadic migration patterns, dispersing up to hundreds of kilometers in response to erratic rainfall and resource pulses, underscoring the biome's influence on avian mobility. Such endemics underscore the need to preserve shrubland connectivity for migration corridors.

Human Impacts and Conservation

Historical and Current Uses

have long utilized shrublands through practices such as controlled burning to manage and promote . In , Aboriginal communities employed for millennia, using low-intensity seasonal fires to clear pathways, attract game animals, and regenerate shrub-dominated landscapes, thereby shaping ecosystems that supported and gathering. Similarly, in Mediterranean shrublands, ancient grazing by has influenced structure for thousands of years, with herders integrating sheep and goats into maquis and phrygana formations to maintain open areas and prevent woody encroachment. Since antiquity, shrublands have provided fuelwood and ; for instance, in the Mediterranean Basin, communities gathered aromatic shrubs like myrtle and for firewood and therapeutic uses, a tradition documented in Roman-era records of wood supplies from scrubby landscapes. Today, shrublands serve as vital rangelands for production, supporting a significant portion of global needs. Approximately 40% of the world's sheep relies on arid and semi-arid rangelands for , contributing to and industries in regions like the Mediterranean and southwestern . Extraction of resources from shrub species continues, including essential oils from like lavender and in Mediterranean maquis, used in perfumery and pharmaceuticals, as well as from shrubs for processing. has emerged as a key use in biodiversity-rich shrublands, such as South Africa's reserves, where reserves like Grootbos Private attract visitors for guided hikes and viewing, generating revenue while promoting conservation awareness. Management techniques in shrublands emphasize sustainable practices to balance human needs with . Rotational grazing, where are moved between paddocks to allow recovery, prevents overbrowsing and maintains shrub cover in rangelands, as demonstrated in long-term studies across semi-arid areas. Shrub planting initiatives, often using , help control on degraded slopes by stabilizing and improving water infiltration, particularly in Mediterranean and arid zones prone to degradation. These approaches underpin the economic value of shrublands, which provide supporting global production worth tens of billions annually through enhanced productivity and reduced costs. Shrublands hold cultural significance in various traditions, often symbolizing resilience and spiritual connection. In North American sagebrush shrublands, Native American groups like the and incorporate white sage () in rituals for purification, healing, and ceremonies, burning it to cleanse spaces and invoke protection, a practice tied to the plant's deep-rooted role in tribal and daily life.

Threats and Protection Efforts

Shrublands face significant threats from primarily driven by agricultural expansion, with losses estimated at up to 66% in regions like the states since 1950. , such as cheatgrass (), exacerbate degradation by altering fire regimes, reducing native , and fragmenting habitats across western North American shrublands. further compounds these pressures through shifts in patterns, with projections indicating moderate decreases of 10–20% in some shrubland areas, leading to increased drought stress and vegetation shifts. Alterations in fire regimes, particularly through long-term suppression, have contributed to the rise of megafires that devastate shrubland ecosystems; for instance, the 2019–2020 Australian bushfires burned over 18 million hectares of vegetation, including extensive shrubland areas, highlighting the risks of fuel accumulation. More recently, global wildfires in 2024 burned an area larger than , affecting shrubland ecosystems worldwide and exposing over 100 million people to risks. These events underscore how human interventions in natural fire cycles, combined with drier conditions, amplify wildfire intensity and frequency in shrublands worldwide. In 2024, severe droughts in led to widespread dieback in shrublands, illustrating ongoing climate-induced threats. Conservation efforts include the designation of protected areas, which cover approximately 17% of the Province encompassing key shrubland hotspots like South Africa's as of 2024. Restoration initiatives employ soil seed banks to preserve native shrub species and prescribed burns to mimic natural fire regimes, reducing dominance and promoting regeneration in degraded areas. Policy frameworks support these protections, with the assessing the extinction risk of numerous shrub species, including 262 endemic European shrubs evaluated for conservation priorities. Internationally, the Convention on Biological Diversity's Global Biodiversity Framework targets conserving at least 30% of terrestrial areas, including shrublands, by 2030 through expanded protected areas and restoration measures. Human uses, such as , often intensify these threats by accelerating conversion.

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