Ecology and habitats
- Related Topics:
- chactid
- diplocentrid
- bothriurid
- chaerilid
- vejovid
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Scorpions are largely nocturnal and hide during the day in the confines of their burrows, in natural cracks, or under rocks and bark. Individuals become active after darkness has fallen and cease activity sometime before dawn. Because scorpions fluoresce under ultraviolet light, biologists can study their natural behaviour and ecology by using portable camping lights equipped with ultraviolet (black-light) bulbs. On a moonless night, scorpions can be seen at distances of 10 metres (33 feet).
Scorpion habitats range from the intertidal zone to snow-covered mountains. Several species live in caves, with one species (Alacran tartarus) found at depths of more than 800 metres (2,600 feet). Some species have specific habitat requirements. For example, sand-dwelling (psammophilic) species exhibit a morphology that both adapts and restricts them to living in this substrate. Movable bristles (setae) form combs on the legs that increase the surface area and allow them to walk on sand without sinking or losing traction. Lithophilic (“stone-loving”) species such as the South African rock scorpion (Hadogenes troglodytes) are found only on rocks. They possess stout spinelike setae that operate in conjunction with highly curved claws to provide the legs with a strong grip on rock surfaces. They can move rapidly along surfaces at any angle, even upside down.
Other species show adaptability in habitat use. The European Euscorpius carpathicus lives above ground but also occupies caves and intertidal zones. Scorpio maurus can be found from sea level in Israel to above 3,000 metres (9,900 feet) in the Atlas Mountains of Africa, thousands of kilometres to the west.
In some habitats scorpions are one of the most successful and important members in terms of density, diversity, population, biomass, and role in community ecology. Many species can locally attain densities of one or more individuals per square metre. Vaejovis littoralis, an intertidal scorpion from Baja California, Mexico, exhibits the highest density, from 2 to more than 12 per square metre along the high-tide mark. Since adult scorpions commonly weigh 0.5 to 5 grams (0.02 to 0.2 ounce), the biomass of the population is high. In some desert areas the biomass of scorpions exceeds that of all other animals except termites and ants.
Several factors contribute to scorpions’ evolutionary success. Although they are not particularly diverse morphologically, scorpions are quite adaptable in terms of ecology, behaviour, physiology, and life history. Some species can be supercooled below the freezing point for weeks yet return within hours to normal levels of activity. Others survive total immersion under water for as long as one or two days. Desert scorpions can withstand temperatures of 47 °C (117 °F), which is several degrees higher than the lethal temperatures for other desert arthropods.
Associations
Despite being venomous predators, scorpions are valuable as prey because many are relatively large and quite abundant. Birds (mostly owls), lizards, a few small snakes, mammals (some rodents and carnivores), and frogs and toads all eat scorpions. A few vertebrates even specialize on scorpions, at least seasonally. Some scorpions are their own worst enemies, with both cannibalism and predation on other species being common. Such predation can be a major mortality factor and may limit the abundance and distribution of some species. A few large arthropods (spiders, solpugids, centipedes) also eat scorpions.
Scorpions exhibit several antipredator adaptations. The most obvious is the venom-conducting stinger. Venom has dual functions: offensive and defensive. One of its chemical components is toxic to arthropods (for prey capture), while another is active against vertebrates (for predator deterrence). Nocturnal activity and scorpions’ tendency to keep hidden may have evolved to avoid predation. Most species are active for only a few hours on 20 to 50 percent of all nights in a year. Many predators, however, are able to handle scorpions safely. Most vertebrate predators will bite or break off the scorpion’s tail. Some vertebrates and arthropods are immune to scorpion venom, even from species that are lethal to humans.
The vast majority of scorpions are nonsocial, solitary animals that interact only at birth, during courtship, or for cannibalism. They are often so aggressive that they are usually considered “inveterate cannibals.” A few, however, exhibit social behaviour. Some overwinter in aggregations with individuals of their own species, usually under bark or in fallen trees. A few extend the mother-offspring association for weeks to months or even years. In some cases (e.g., emperor scorpions) offspring may remain with the family group even as adults, and some of these family groups cooperate in prey capture.
Form and function
The anatomy of scorpions has changed little since the Silurian Period (443 to 417 million years ago). Consequently, their body plan is relatively primitive. Segments and associated structures were lost or fused during evolution from ancestral arthropods and arachnids to more highly evolved descendants. Scorpions have more segments (18) than any other arachnids and are strongly segmented in the design of the heart and nervous system. The possession of book lungs rather than tracheae for respiration is also primitive.
External features
The three major regions that form the body, from front to rear, are the prosoma, the mesosoma, and the metasoma. The mesosoma and the metasoma together form the abdomen, or opisthosoma. The prosoma has six segments, each with a pair of appendages. The three-segmented chelicerae that arise from the first segment are pincerlike (chelate) and serve to masticate food. The pedipalps originate in the second segment and terminate in pincers. Pedipalps are used for a variety of purposes, including prey capture, defense, courtship, and burrow excavation. A pair of legs are found on each of segments three through six. The pedipalps and legs are composed of seven segments (from the body outward: coxa, trochanter, femur, patella, tibia, basitarsus, and tarsus). The legs end in tarsal claws used to grasp surfaces during walking. One central pair of eyes and from zero to five lateral pairs are set into the dorsal carapace that covers the prosoma.
The mesosoma has seven segments. The first (pregenital) segment is reduced and bears the sternum, while the second (genital) bears the ventral gonopore, which is covered. The unique comblike pectines arise from the genital segment. A pair of book lungs are found on the ventral side of mesosomal segments three through six. The seventh mesosomal segment marks the end of the “body.” The mesosoma is covered dorsally by plates that are separated from each other by a flexible membrane. The tail is composed of the five-segmented cylindrical metasoma and a telson bearing the stinger. The anus exits at the end of the fifth metasomal segment.
The exoskeleton is composed of chitinous cuticle overlain by impermeable epicuticular waxes. Growth is accompanied by molts (ecdysis). Scorpions increase in weight until the exoskeleton has become too small to allow further growth. A new exoskeleton is then secreted by the epidermis under the old. During this process some materials are reclaimed from the old cuticle. Scorpions, like other arachnids, probably increase blood pressure just before molting to cause the cuticle to rupture at the side and front margins of the carapace. The chelicerae, pedipalps, legs, and body are withdrawn from the old cuticle over a period of approximately 12 hours. Scorpions then probably increase blood pressure to expand body volume temporarily while the new cuticle hardens. This allows room for future growth. As the cuticle hardens and darkens, it gradually acquires the ability to fluoresce under ultraviolet light.