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The Mud-Dauber Wasp Is One of the More Commonly Encountered Wasps in Sydney

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Yellow jack ground wasp paper wasp (umbrella wasp) Common paper wasps are social insects, who build nests of grey papery material around the home often under eaves, pergolas or in vegetation. Description Polistes humilis or common paper wasps are generally slender with long thin wings. They are 10-15 millimetres long, tan in colour with darker bands and some yellow on the face. Other species of paper wasps are larger or smaller and differently coloured. Paper wasps make nests of grey papery wood fibre material. The nests are cone-shaped, becoming round as more cells are added. Nests are a maximum diameter of 10-12 centimetres, with numerous hexagonal cells underneath, some with white caps. Nests are exposed and suspended by a short stalk under an overhang, often on a pergola, the eaves of a roof or in a shrub or tree. Wasps cluster on the nest or forage in the garden and around buildings. Paper wasps are found across mainland southern Australia including: • southern Queensland • New South Wales • the Australian Capital Territory • Victoria • South Australia • southern Western Australia. Life history Paper wasps are a social wasp consisting of small colonies of 12-20 individuals. Adult wasps feed on nectar and make ‘paper’ nests by mixing saliva and wood fibres. Nests are a nursery where larvae are kept one to each cell. The larvae are fed on chewed-up caterpillars caught by the adults. The cells are then capped and the larvae pupate. Most paper wasps die in autumn or winter, while some hibernate to start new nests next season. Pest status and management Paper wasps have some beneficial value as predators of pest caterpillars, however they have a painful sting and will attack any person approaching or disturbing their nest. Nests likely to be disturbed represent a hazard and should be avoided during the day. Ignore nests where they are high or otherwise out of the way. Nests in high traffic areas such as doorways, pergolas or carports can be sprayed from the side at night with a registered aerosol wasp insecticide. Repeat spray two nights afterwards then remove and destroy the nest. Use a red light (for example, red cellophane over a torch lens) if light is needed when spraying at night. In the event of a sting apply a cold pack. Seek medical attention if the victim is known to be allergic or if symptoms become more severe. Entomology is not currently researching paper wasps. The term wasp is typically defined as any insect of the order Hymenoptera and suborder Apocrita that is neither a bee nor ant[1]. Almost every pest insect species has at least one wasp species that preys upon it or parasitizes it, making wasps critically important in natural control of their numbers, or natural biocontrol. Parasitic wasps are increasingly used in agricultural pest control as they prey mostly on pest insects and have little impact on crops. Taxonomy Wasp stinger, with droplet of venom The majority of wasp species (well over 100,000 species) are "parasitic" (technically known as parasitoids), and the ovipositor is used simply to lay eggs, often directly into the body of the host. The most familiar wasps belong to Aculeata, a division of Apocrita, whose ovipositors are adapted into a venomous sting, though a great many aculeate species do not sting. Aculeata also contains ants and bees, and many wasps are commonly mistaken for bees, and vice-versa. In a similar respect, insects called "velvet ants" (the family Mutillidae) are technically wasps. The suborder Symphyta, known commonly as sawflies, differ from members of Apocrita by lacking a sting, and having a broader connection between the mesosoma and metasoma. In addition to this, Symphyta larvae are mostly herbivorous and "caterpillarlike", whereas those of Apocrita are largely predatory or parasitoids. A much narrower and simpler but popular definition of the term wasp is any member of the aculeate family Vespidae, which includes (among others) the genera known in North America as yellowjackets (Vespula and Dolichovespula) and hornets (Vespa); in many countries outside of the Western Hemisphere, the vernacular usage of wasp is even further restricted to apply strictly to yellowjackets (e.g., the "common wasp"). Categorization The various species of wasps fall into one of two main categories: solitary wasps and social wasps. Adult solitary wasps generally live and operate alone, and most do not construct nests (below); all adult solitary wasps are fertile. By contrast, social wasps exist in colonies numbering up to several thousand strong and build nests—but in some cases not all of the colony can reproduce. In the more advanced species, just the wasp queen and male wasps can mate, whilst the majority of the colony is made up of sterile female workers. The following characteristics are present in most wasps: Characteristics * Two pairs of wings (except wingless or brachypterous forms in all female Mutillidae, Bradynobaenidae, many male Agaonidae, many female Ichneumonidae, Braconidae, Tiphiidae, Scelionidae, Rhopalosomatidae, Eupelmidae, and various other families). * An ovipositor, or stinger (which is only present in females because it derives from the ovipositor, a female sex organ). * Few or no thickened hairs (in contrast to bees); except Mutillidae, Bradynobaenidae, Scoliidae. * Nearly all wasps are terrestrial; only a few specialized parasitic groups are aquatic. * Predators or parasitoids, mostly on other terrestrial insects; most species of Pompilidae (e.g. tarantula hawks), specialize in using spiders as prey, and various parasitic wasps use spiders or other arachnids as reproductive hosts. Wasps are critically important in natural biocontrol. Almost every pest insect species has at least one wasp species that is a predator or parasite upon it. Parasitic wasps are also increasingly used in agricultural pest control. Wasps also constitute an important part of the food chain. Anatomy and gender Anatomically, there is a great deal of variation between different types of wasp. Like all insects, wasps have a hard exoskeleton covering their three main body parts. These parts are known as the head, metasoma and mesosoma. Wasps also have a constricted region joining the first and second segments of the abdomen (the first segment is part of the mesosoma, the second is part of the metasoma) known as the petiole. Like all insects, wasps have three sets of two legs. In addition to their compound eyes, wasps also have several simple eyes known as ocelli. These are typically arranged in a triangular formation just forward of an area of the head known as the vertex. It is possible to distinguish between certain wasp species genders based on the number of divisions on their antennae. Male Yellowjacket wasps for example have 13 divisions per antenna, while females have 12. Males can in some cases be differentiated from females by virtue of the fact that the upper region of the male's mesosoma (called the tergum) consists of an additional terga. The total number of terga is typically six. The difference between sterile female worker wasps and queens also varies between species but generally the queen is noticeably larger than both males and other females. Wasps can be differentiated from bees, which have a flattened hind basitarsus. Unlike bees, wasps generally lack plumose hairs. They vary in the number and size of hairs they have between species. Generally wasps are parasites or parasitoids as larvae, and feed only on nectar as adults. Many wasps are predatory, using other insects (often paralyzed) as food for their larvae. A few social wasps are omnivorous, feeding on a variety of fallen fruit, nectar, and carrion. Some of these social wasps, such as yellowjackets, may scavenge for dead insects to provide for their young. In many social species the larvae provide sweet secretions that are fed to the adults. In parasitic species, the first meals are almost always provided by the animal that the adult wasp used as a host for its young. Adult male wasps sometimes visit flowers to obtain nectar to feed on in much the same manner as honey bees. Occasionally, some species, such as yellowjackets, invade honey bee nests and steal honey and/or brood.[citation needed] With most species, adult parasitic wasps themselves do not take any nutrients from their prey, and, much like bees, butterflies, and moths, those that do feed as adults typically derive all of their nutrition from nectar. Parasitic wasps are typically parasitoids, and extremely diverse in habits, many laying their eggs in inert stages of their host (egg or pupa), or sometimes paralyzing their prey by injecting it with venom through their ovipositor. They then insert one or more eggs into the host or deposit them upon the host externally. The host remains alive until the parasitoid larvae are mature, usually dying either when the parasitoids pupate, or when they emerge as adults. The type of nest produced by wasps can depend on the species and location. Many social wasps produce paper pulp nests on trees, in attics, holes in the ground or other such sheltered areas with access to the outdoors. By contrast solitary wasps are generally parasitic or predatory and only the latter build nests at all. Unlike honey bees, wasps have no wax producing glands. Many instead create a paper-like substance primarily from wood pulp. Wood fibers are gathered locally from weathered wood, softened by chewing and mixing with saliva. The pulp is then used to make combs with cells for brood rearing. More commonly, nests are simply burrows excavated in a substrate (usually the soil, but also plant stems), or, if constructed, they are constructed from mud. Solitary wasps The nesting habits of solitary wasps are more diverse than those of social wasps. Mud daubers and pollen wasps construct mud cells in sheltered places typically on the side of walls.
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  • Occurrence and Biology of Pseudogonalos Hahnii (Spinola, 1840) (Hymenoptera: Trigonalidae) in Fennoscandia and the Baltic States

    Occurrence and Biology of Pseudogonalos Hahnii (Spinola, 1840) (Hymenoptera: Trigonalidae) in Fennoscandia and the Baltic States

    © Entomologica Fennica. 1 June 2018 Occurrence and biology of Pseudogonalos hahnii (Spinola, 1840) (Hymenoptera: Trigonalidae) in Fennoscandia and the Baltic states Simo Väänänen, Juho Paukkunen, Villu Soon & Eduardas Budrys Väänänen, S., Paukkunen, J., Soon, V. & Budrys, E. 2018: Occurrence and bio- logy of Pseudogonalos hahnii (Spinola, 1840) (Hymenoptera: Trigonalidae) in Fennoscandia and the Baltic states. Entomol. Fennica 29: 8696. Pseudogonalos hahnii is the only known species of Trigonalidae in Europe. It is a hyperparasitoid of lepidopteran larvae via ichneumonid primary parasitoids. Possibly, it has also been reared from a symphytan larva. We report the species for the first time from Estonia, Lithuania and Russian Fennoscandia, and list all known observations from Finland and Latvia. An overview of the biology of the species is presented with a list of all known host records. S. Väänänen, Vantaa, Finland; E-mail: [email protected] J. Paukkunen, Finnish Museum of Natural History, Zoology Unit, P.O. Box 17, FI-00014 University of Helsinki, Finland; E-mail: [email protected] V. Soon, Natural History Museum, University of Tartu, Vanemuise 46, 51014 Tartu, Estonia; E-mail: [email protected] E. Budrys, Nature Research Centre, Akademijos 2, LT-08412 Vilnius, Lithuania; E-mail: [email protected] Received 27 June 2017, accepted 22 September 2017 1. Introduction ovipositor with Aculeata (Weinstein & Austin 1991). The trigonalid ovipositor is reduced and Trigonalidae is a moderately small family of par- hidden within the abdomen and it is not known if asitic wasps of little over 100 species and about it is used in egg placement (Quicke et al. 1999).