periodical cicada image  
@www.magicicada.org  
  


Visit Cicada Central

Visit Cicada Mania

Insect Singers



Follow Magicicada2012 on Facebook

Donate $5 to support the mapping project
 
 
 
 

 
 

2014 will be an exciting year for periodical cicadas. 13-year Brood XXII, the Lower Mississipian Brood, will emerge in April and May. Then, 17-year Brood III, the Iowan Brood, will emerge in Iowa and north western Illinois.


The 2014 emergence of periodical cicadas will be extraordinary. First, 13-year Brood XXII will emerge in the Lower Mississippi River Valley. This brood contains Magicicada tredecim, M. tredecassini, and M. tredecula. Adults of Brood XXII are expected to start emerging in the Baton Rouge area in late April.

In Mid- to late May, 17-year Brood III will emerge in Iowa and north western Illinois. Magicicada septendecim, M. cassini, and M. septendecula are all found in this brood. Brood III occurs in close proximity to 13-year Brood XIX , and the stability of the boundary of these broods has been a topic of considerable research interest.

Brood III was mapped in detail in 1997, and 2014 will allow us to see whether the brood range has shifted in the intervening 17 years.

Note that some older maps of 17-year Brood III suggest that the brood has a disjunct eastern portion in DeWitt County, IL. We searched for this disjunct in 1997 and found no evidence that it exists.

General periodical cicada information

Periodical cicadas are unique in their combination of long, prime-numbered life cycles (13 or 17 years), precisely timed mass emergences, and active choruses.

Periodical cicadas are found only in eastern North America. There are seven species -- four with 13-year life cycles and three with 17-year cycles. The three 17-year species are generally northern in distribution, while the 13-year species are generally southern and midwestern. The periodical cicadas can be divided into three species groups (-decim, -cassini, and -decula) with slight ecological differences. Magicicada are so synchronized developmentally that they are nearly absent as adults in the 12 or 16 years between emergences. When they do emerge after their long juvenile periods, they do so in huge numbers, forming much denser aggregations than those achieved by most other cicadas. Periodical cicada emergences in different regions are not synchronized, and different populations comprise the 15 largely parapatric periodical cicada “Broods,” or year-classes.

Many people know periodical cicadas by the name "17-year locusts" or "13-year locusts", but they are not true locusts, which are a type of grasshopper. Their uniqueness has given them a special appeal and cultural status. Members of the Onondaga Nation near Syracuse NY maintain the oral tradition of being rescued from famine by periodical cicadas. Early European colonists viewed periodical cicadas with a mixture of religious apprehension and loathing. Modern Americans maintain numerous websites to assist in planning weddings, graduations, and other outdoor activities around Magicicada emergences.

Magicicada adults have black bodies and striking red eyes and orange wing veins, with a black "W" near the tips of the forewings. Most emerge in May and June. Some of the annual cicada species are sometimes mistaken for the periodical cicadas, especially those in the genera Diceroprocta and Okanagana; these other species emerge somewhat later in the year but may overlap with Magicicada. The Okanagana species are the most potentially confusing because some have similar black-and-orange coloration. Other Common North American non-periodical cicadas include the large, greenish "dog-day" cicadas (genus Tibicen) found throughout the U.S. in the summer. Non-periodical cicadas are often called "annual cicadas" (even though they typically have multiple-year life cycles) because in a given location adults emerge every year. The best way to identify cicada species is by the sounds that they make, because cicada songs are nearly always species-specific.

Female periodical cicadas have a pointed abdomen with an ovipositor for laying eggs. The ovipositor is sheathed and not clearly visible in this photograph.

Males have a blunter abdomen.

Males also have ribbed tymbals located on the sides of the first abdominal segment, just behind the point of attachment of the hindwings. The lowest photo shows a male M. septendecim with wings removed to show the tymbal.

Cicadas do not possess special defensive mechanisms -- they do not sting or bite. The ovipositor is used only for laying eggs and the mouthparts are used only for feeding on twigs; thus, periodical cicadas can hurt you only if they mistake you for a tree branch! When approached, a cicada will simply fly away. If handled, both males and females struggle to fly, and males make a loud defensive buzzing sound that may startle but is otherwise harmless. Cicadas are not poisonous or known to transmit disease.

Periodical cicadas may cause physical damage to small trees or shrubs if too many feed from the plant or lay eggs in its twigs; such damage can cause "flagging," or breaking of peripheral twigs. When these twigs die, they become brown. Orchard and nursery owners should avoid planting young trees or shrubs in the years preceding an emergence of periodical cicadas, because young trees may be harmed by severe flagging. Mature trees and shrubs, however, usually survive even dense emergences of cicadas without apparent distress. This can be difficult to believe in the month or so following a large emergence when many deciduous trees turn brown due to the breakage and death of peripheral twigs. As serious as it may appear, such damage is apparently minor.

This tree shows damage from flagging. The simplest and possibly most effective way to protect small trees and shrubs is to physically prevent cicadas from feeding and ovipositing by covering the plants with screening material. Periodical cicadas are often too numerous to make application of pesticides practical.

Other than the concern by owners of fruit orchards and nurseries, periodical cicadas are not regarded as pests, except maybe by those who tire of the din of their choruses.

Cicada juveniles are called "nymphs" and live underground, sucking root fluids for food. Periodical cicadas spend five juvenile stages in their underground burrows, and during their 13 or 17 years underground they grow from approximately the size of a small ant to nearly the size of an adult. The photographs below show 4-year old Brood III nymphs in underground tunnels.

In the spring of their 13th or 17th year, a few weeks before emerging, the nymphs construct exit tunnels to the surface. These exits are visible as approximately 1/2 inch diameter holes, or as chimney-like mud "turrets" the nymphs sometimes construct over their holes.

On the night of emergence, nymphs leave their burrows after sunset (usually), locate a suitable spot on nearby vegetation, and complete their final molt to adulthood. Shortly after ecdysis (molting) the new adults appear mostly white, but they darken quickly as the exoskeleton hardens. The cues that determine the particular night on which the nymphs emerge and molt are not well understood, but soil temperature probably plays an important role. Sometimes a large proportion of the population emerges in one night. Newly-emerged cicadas spend roughly four to six days as "teneral" adults before they harden completely (possibly longer in cool weather); they do not begin adult behavior until this period of maturation is complete.

It appears that the particular night of emergence may be determined by the soil temperature; nymphs emerge when the soil temperature inside the exit tunnel (and therefore the body temperature of the nymph) exceeds approximately 64 degrees F. Because emergence is temperature-dependent, periodical cicadas tend to emerge earlier in southern and lower-elevation locations. For example, cicadas in South Carolina often begin to emerge in late April, while those in southern Michigan do not appear until June. The best way to predict the time of emergence for your area is to check records from the prior emergence in that location, by asking longtime residents or by searching local newspaper archives. The date of emergence does not vary much between generations, although unusual springtime weather conditions may accelerate or delay the emergence by a week or so.

After their short teneral period, males begin producing species-specific calling songs and form aggregations (choruses) that are sexually attractive to females. Males in these choruses alternate bouts of singing with short flights until they locate receptive females.

Contrary to popular belief, adults do feed by sucking plant fluids; adult cicadas will die if not provided with living woody vegetation on which to feed (see picture below of Magicicada septendecula feeding. Adult Magicicada feed from a wide variety of deciduous plants and shrubs, but usually not from grasses. The piercing-and-sucking mouthparts are visible just behind the forelegs).

Mated females excavate a series of Y-shaped eggnests in living twigs and lay up to twenty eggs in each nest. A female may lay as many as 600 eggs.

A female Magicicada septendecim starting to construct an eggnest. The red arrow points to the tip of her ovipositor, which she is about to insert into the branch.

A photograph of Magicicada eggnests.

When cut open, the eggnests look like this (note the small white eggs stacked in the nest)

After six to ten weeks, the eggs hatch and the new first-instar nymphs drop from the trees, burrow underground, locate a suitable rootlet for feeding, and begin their long 13- or 17-year development.

By the time that the nymphs hatch, the adults have died. This photograph shows piles of dead adults under an oak tree.

Periodical cicadas achieve astounding population densities, as high as 1.5 million per acre. Densities of tens to hundreds of thousands per acre are more common, but even this is far beyond the natural abundance of most other cicada species. Apparently because of their long life cycles and synchronous emergences, periodical cicadas escape natural population control by predators, even though everything from birds to spiders to snakes to dogs eats them opportunistically when they do appear. Magicicada population densities are so high that predators apparently eat their fill without significantly reducing the population (a phenomenon called "predator satiation"), and the predator populations cannot build up in response because the cicadas are available as food above ground only once every 13 or 17 years.

Individual periodical cicadas are slower, less flighty, and easier to capture than other cicadas, probably because the safety afforded by their great numbers means that the risks of predation for an individual are low. Explaining the evolution of such an unusual life strategy is one of the most difficult problems for periodical cicada biologists.

Magicicada do not have any specialized predators, but periodical cicadas are subject to infection by the specialized fungal parasite Massospora cicadina Peck. The effects of this fungus on Magicicada population densities are not well understood.

During an emergence of periodical cicadas, both sexual and asexual forms of the fungus are present. Cicadas infected early in the emergence develop asexual spores, which become evident as the rear of the infected individual's abdomen breaks off, exposing a white, chalky mass of spores. This infection sterilizes the cicada but does not kill it immediately. These spores spread among the population, infecting other cicadas who will develop a secondary infection and whose abdomens will later break open, releasing sexual resting spores to infect the next generation of cicadas.

Cicadas sometimes fail to properly inflate their wings after molting; such individuals can be found in low vegetation in any emergence. There may be a tendency for this to occur more often in certain situations. Possible explanations include crowding (during molting) and use of lawn chemicals.

The cicadas in this photograph came from a 1990 emergence in a suburban front yard near Chicago. Many of the cicadas in this area had deformed wings.

Molting can go wrong in other ways too. The cicada in this photograph failed to emerge completely from its nymphal skin. It died partially emerged.

Literature

  • Martin, A., and C. Simon. 1988. Anomalous distribution of nuclear and mitochondrial DNA markers in periodical cicadas. Nature 336:237-239.
  • Martin, A., and C. Simon. 1990. Differing Levels of Among-Population Divergence in the Mitochondrial DNA of Periodical Cicadas Related to Historical Biogeography. Evolution 44:1066-1080.
  • Marshall, D. C., and J. R. Cooley. 2000. Reproductive Character Displacement and Speciation in Periodical Cicadas, with Description of a New Species, 13-Year Magicicada neotredecim. Evolution 54:1313-1325.
  • Simon, C., J. Tang, S. Dalwadi, G. Staley, J. Deniega, and T. R. Unnasch. 2000. Genetic Evidence for Assortative Mating between 13-Year Cicadas and Sympatric "17-Year Cicadas with 13-Year Life Cycles" Provides Support for Allochronic Speciation. Evolution 54:1326-1336.
  • Cooley, J. R., and D. C. Marshall. 2001. Sexual signaling in periodical cicadas, Magicicada spp. (Hemiptera: Cicadidae). Behaviour 138:827-855.
  • Cooley, J. R., C. Simon, D. C. Marshall, K. Slon, and C. Ehrhardt. 2001. Allochronic speciation, secondary contact, and reproductive character displacement in periodical cicadas (Hemiptera: Magicicada spp.): genetic, morphological, and behavioural evidence. Mol. Ecol. 10:661-671.
  • Cooley, J. R., D. C. Marshall, K. B. R. Hill, and C. Simon. 2006. Reconstructing asymmetrical reproductive character displacement in a periodical cicada contact zone. Journal Of Evolutionary Biology 19:855-868.
  • Cooley, J. R., G. Kritsky, J. D. Zyla, M. J. Edwards, C. Simon, D. C. Marshall, K. B. R. Hill, and R. Krauss. 2009. The Distribution of Periodical Cicada Brood X. The American Entomologist 55:106-112.

 

 
Periodical Cicada Maps