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{{Short description|Species of beetle}}
{{Taxobox
{{Good article}}
{{Speciesbox
| name = Emerald ash borer | name = Emerald ash borer
| image = Agrilus planipennis 001.jpg | image = Agrilus planipennis 001.jpg
| image_width = 100px | genus = Agrilus
| regnum = ]ia | species = planipennis
| authority = ], 1888
| phylum = ]a
| classis = ]a | synonyms =
*''Agrilus feretrius'' <small>]</small>
| ordo = ]
*''Agrilus marcopoli'' <small>Obenberger</small><ref>{{cite journal |title=Data Sheets on Quarantine Pests: ''Agrilus planipennis'' |journal=OEPP/EPPO Bulletin |volume=35 |issue=3 |pages=436–438 |year=2005 |doi=10.1111/j.1365-2338.2005.00844.x |doi-access=free}}</ref>
| familia = ]
| genus = '']''
| species = '''''A. planipennis'''''
| binomial = ''Agrilus planipennis''
| binomial_authority = ], 1888
| synonyms =
* ''Agrilus feretrius'' <small>]</small>
* ''Agrilus marcopoli'' <small>Obenberger</small>
| synonyms_ref = <ref>{{cite journal |title= Data Sheets on Quarantine Pests: ''Agrilus planipennis'' |journal= OEPP/EPPO Bulletin |volume= 35 |issue= 3 |pages= 436–438 |publisher= European and Mediterranean Plant Protection Organization |year= 2005 |url= http://www.eppo.int/QUARANTINE/insects/Agrilus_planipennis/DS_Agrilus_planipennis.pdf?utm_source=www.eppo.org&utm_medium=int_redirect |doi= 10.1111/j.1365-2338.2005.00844.x}}</ref>
}} }}
'''''Agrilus planipennis''''', commonly known as the '''emerald ash borer''' (EAB) is a green ] native to eastern Asia that feeds on ]. In its native range, it is typically found at low densities and is not considered a significant pest. Outside its native range, it is an ] and is highly destructive to ] native to North America that local governments are attempting to control with monitoring, diversifying urban tree species, insecticides, and ].


The '''emerald ash borer''' ('''''Agrilus planipennis'''''), also known by the acronym '''EAB''', is a green ] or jewel beetle native to north-eastern Asia that feeds on ] (''Fraxinus'' spp.). Females lay eggs in bark crevices on ash trees, and larvae feed underneath the bark of ash trees to emerge as adults in one to two years. In its native range, it is typically found at low densities and does not cause significant damage to trees native to the area. Outside its native range, it is an ] and is highly destructive to ] native to Europe and North America. Before it was found in North America, very little was known about the emerald ash borer in its native range; this has resulted in much of the research on its biology being focused in North America. Local governments in North America are attempting to control it by monitoring its spread, diversifying tree species, and through the use of ]s and ].
==Range==
The natural range of the emerald ash borer is eastern ], northern ], ], and ].<ref>{{cite web |title= ''Agrilus planipennis'' (insect) |work= Global Invasive Species Database |publisher= ISSG-IUCN |date= August 14, 2006 |url= http://www.issg.org/database/species/ecology.asp?si=722&fr=1&sts=sss&lang=EN }}</ref> In is invasive in North America where it has a core population in ] and surrounding states and provinces. Populations are more scattered outside the core area, and the edges of its known distribution range north to the upper peninsula of Michigan, south to northern Louisiana, west to Colorado, and east to Massachusetts <ref name="USDA info">{{cite web | title =Emerald ash borer | publisher =USDA Forest Service | url =http://www.emeraldashborer.info | accessdate = July 5, 2015}}</ref>


==Identification== ==History==
The French priest and naturalist ] collected a specimen of the emerald ash borer during one of the trips he took through imperial China in the 1860s and 1870s. He found the beetle in Beijing and sent it back to France, where a brief ] by the entomologist ] was published in the ''Revue d'Entomologie'' in 1888.<ref>{{cite news |last= Miller |first= Matthew |title= Battle of the Ash Borer: Decades after Beetles Arrived in Michigan, Researchers Looking to Slow Devastation |url= http://www.lansingstatejournal.com/interactive/article/20140727/NEWS01/307270001/Battle-ash-borer-Decades-after-beetles-arrived-Michigan-researchers-looking-slow-devastation |work= ] }}</ref> Adults are a bright metallic green. ] are typically a darker green, but can also have copper hues. EAB is the only North American species of '']'' with a bright red upper abdomen when viewed with the wings and elytra spread. The species also has a small spine found at the tip of the abdomen and ] antennae that begin at the fourth antennal segment.<ref name="EABID">{{Citeweb| last =Parsons | first =Gary L. | title =Emerald ash borer: A guide to identification and comparison to similar species | publisher =USDA | date =November 2008 | url = http://www.emeraldashborer.info/files/eab_id_guide.pdf | accessdate = August 15, 2014}}</ref>
]


French priest and naturalist ] collected a specimen of the species during one of his trips through ] in the 1860s and 1870s. He found the beetle in Beijing and sent it to France, where the first brief ] of ''Agrilus planipennis'' by the entomologist ] was published in the ''Revue d'Entomologie'' in 1888.<ref name="Taxonhistory">{{cite news |last=Miller |first=Matthew |title=Battle of the Ash Borer: Decades after Beetles Arrived in Michigan, Researchers Looking to Slow Devastation |url=http://www.lansingstatejournal.com/story/news/local/2014/09/03/michigan-emerald-ash-borer/14796695/ |work=]}}</ref> Unaware of Fairmaire's description, a separate description naming the species as ''Agrilus marcopoli'' was published in 1930 by ].<ref name="Taxonhistory"/>
== Hosts ==
EAB primarily infest and can cause significant damage to ] including ], ], ], and ].<ref name="Poland and McCullough 2006">{{cite journal | last =Poland | first =T. | last2 =McCullough |first2=D. | title =Emerald ash borer: invasion of the urban forest and the threat to North America’s ash resource. | journal =Journal of Forestry | volume =104 | pages =118–124 | date =2006 | url =http://www.nrs.fs.fed.us/pubs/jrnl/2006/nc_2006_Poland_003.pdf}}</ref> In its native range, emerald ash borer is only a sporadic pest on native trees as population densities typically do not reach levels lethal to healthy trees.<ref name="Wang et al. 2010">{{cite journal |last= Wang |first= Xiao-Yi | title= The biology and ecology of the emerald ash borer, ''Agrilus planipennis'', in China |journal= Journal of Insect Science |date= 2010 |volume= 10 |page= 128 |url= http://jinsectscience.oxfordjournals.org/content/10/1/128 |display-authors=etal}}</ref>


==Identification==
Damage occurs in infested trees due to larval feeding. The serpentine feeding galleries of the larvae disrupt the flow of nutrients and water effectively girdling the tree. On susceptible species or in the absence of organisms that suppress emerald ash borer populations, the tree will eventually no longer be able to transport sufficient nutrients to the leaves to survive.<ref name="Herms et al. 2013"/> EAB has also been found infesting ], but it was not apparent whether the trees were healthy when first infested, or were already in decline due to drought.<ref>{{cite web | url=http://web.extension.illinois.edu/lmw/eb255/entry_9199/ | title=Emerald Ash Borer attacking White Fringe Tree | accessdate=14 December 2014}}</ref>
Adult beetles are typically bright metallic green and about {{cvt|8.5|mm|in|sp=us}} long and {{cvt|1.6|mm|in|sp=us}} wide. ] are typically a darker green, but can also have copper hues. Emerald ash borer is the only North American species of '']'' with a bright red upper abdomen when viewed with the wings and elytra spread. The species also has a small spine found at the tip of the abdomen and ] antennae that begin at the fourth antennal segment.<ref name="EABID">{{Cite web |last=Parsons |first=Gary L. |title=Emerald ash borer: A guide to identification and comparison to similar species |publisher=USDA |date=November 2008 |url=http://www.emeraldashborer.info/files/eab_id_guide.pdf |access-date=August 15, 2014 |archive-date=September 24, 2015 |archive-url=https://web.archive.org/web/20150924000113/http://www.emeraldashborer.info/files/eab_id_guide.pdf |url-status=dead }}</ref> They leave tracks in the trees they damage below the bark that are sometimes visible.<ref>{{Cite web |url=https://www.bioadvanced.com/articles/controlling-emerald-ash-borers |title=Controlling Emerald Ash Borers to Protect Ash Trees &#124; Bioadvanced}}</ref> Adult beetles of other species can often be misidentified by the public.<ref>{{cite web |title=Native Borers and Emerald Ash Borer Look-alikes |url=http://www.emeraldashborer.info/documents/E-2939.pdf |publisher=Michigan State University Extension |access-date=12 March 2017}}</ref><ref>{{Cite journal |last1=Volkovitsh |first1=Mark G. |last2=Orlova-Bienkowskaja |first2=Marina J. |last3=Kovalev |first3=Alexey V. |last4=Bieńkowski |first4=Andrzej O. |title=An illustrated guide to distinguish emerald ash borer (''Agrilus planipennis'') from its congeners in Europe |journal=Forestry: An International Journal of Forest Research |language=en |doi=10.1093/forestry/cpz024 |year=2019 |doi-access=}}</ref>


==Life cycle== ==Life cycle==
The emerald ash borer life cycle can occur over one or two years depending on the time of year of ], the health of the tree, and temperature.<ref name=" USDA-APHIS-ARS-FS">{{Cite journal |last= Gould |first= Juli S. |last2= Bauer |first2= Leah S. |last3= Lelito |first3= Jonathan |last4= Duan |first4= Jian |title= Emerald Ash Borer Biological Control Release and Recovery Guidelines |publisher= USDA-APHIS-ARS-FS |date= May 2013 |url= http://www.aphis.usda.gov/plant_health/plant_pest_info/emerald_ash_b/downloads/EAB-FieldRelease-Guidelines.pdf |format= PDF }}</ref> The emerald ash borer life cycle can occur over one or two years depending on the time of year of ], the health of the tree, and temperature.<ref name=" USDA-APHIS-ARS-FS">{{Cite web |last1=Gould |first1=Juli S. |last2=Bauer |first2=Leah S. |last3=Lelito |first3=Jonathan |last4=Duan |first4=Jian |title=Emerald Ash Borer Biological Control Release and Recovery Guidelines |publisher=USDA-APHIS-ARS-FS |date=May 2013 |url=http://www.aphis.usda.gov/plant_health/plant_pest_info/emerald_ash_b/downloads/EAB-FieldRelease-Guidelines.pdf |access-date=2012-04-27 |archive-date=2019-07-01 |archive-url=https://web.archive.org/web/20190701070750/https://www.aphis.usda.gov/plant_health/plant_pest_info/emerald_ash_b/downloads/EAB-FieldRelease-Guidelines.pdf |url-status=dead}}</ref>


Adult beetles are typically bright metallic green and about {{convert|8.5|mm|in|sp=us}} long and {{convert|1.6|mm|in|sp=us}} wide. After 400–500 accumulated ]s (GDD) at base {{convert|10|°C|°F}}, adults begin to emerge from trees, and peak emergence occurs around 1000 GDD. After emergence, adults feed for one week on ash leaves in the ] before mating, but cause little defoliation in the process.<ref name="Herms et al. 2013">{{cite journal |last= Herms |first= Daniel A. |first2= Deborah G. |last2= McCullough |title= Emerald Ash Borer Invasion of North America: History, Biology, Ecology, Impacts, and Management |journal= Annual Review of Entomology |date= October 2013 |volume= 59 |pages= 13–30 |url= http://www.annualreviews.org/doi/pdf/10.1146/annurev-ento-011613-162051 |doi= 10.1146/annurev-ento-011613-162051|pmid= 24112110 }}</ref> A typical female can live around six weeks and lay approximately 40–70 eggs, but females that live longer can lay up to 200 eggs.<ref name="Herms et al. 2013"/> After 400–500 accumulated ] above {{cvt|10|°C|°F}}, adults begin to emerge from trees in late spring, and peak emergence occurs around 1,000 degree-days. After emergence, adults feed for one week on ash leaves in the ] before mating, but cause little defoliation in the process.<ref name="Herms et al. 2013">{{cite journal |last1=Herms |first1=Daniel A. |first2=Deborah G. |last2=McCullough |title=Emerald Ash Borer Invasion of North America: History, Biology, Ecology, Impacts, and Management |journal=Annual Review of Entomology |date=October 2013 |volume=59 |pages=13–30 |url=https://www.colorado.gov/pacific/sites/default/files/atoms/files/Emerald%20Ash%20Borer%20Invasion%20of%20North%20America.pdf |doi=10.1146/annurev-ento-011613-162051 |pmid=24112110 |access-date=2015-07-24 |archive-date=2020-07-19 |archive-url=https://web.archive.org/web/20200719200146/https://www.colorado.gov/pacific/sites/default/files/atoms/files/Emerald%20Ash%20Borer%20Invasion%20of%20North%20America.pdf |url-status=dead }}</ref> Males hover around trees, locate females by visual cues, and drop directly onto the female to mate. Mating can last 50 minutes, and females may mate with multiple males over their lifespan.<ref name="Poland"/> A typical female can live around six weeks and lay approximately 40–70 eggs, but females that live longer can lay up to 200 eggs.<ref name="Herms et al. 2013"/>


Eggs are deposited between bark crevices, flakes, or cracks and hatch about two weeks later. Eggs are approximately {{convert|0.6|to|1.0|mm|in|2|sp=us}} in diameter, and are initially white, but later turn reddish-brown if fertile.<ref name="Herms et al. 2013"/><ref name=" USDA-APHIS-ARS-FS"/> After hatching, larvae chew through the bark to the ] and ] where they feed and develop. Emerald ash borer has four larval ]s. By feeding, larvae create long serpentine galleries. Fully mature fourth-instar larvae are {{convert|26|to|32|mm|in|sp=us}} long.<ref name="USDA-APHIS-ARS-FS"/> In fall, mature fourth-instars excavate chambers in the sapwood or outer bark where they fold into a J-shape. These J-shaped larvae shorten into prepupae and develop into pupae and adults the following spring. To exit the tree, adults chew holes from their chamber through the bark, which leaves a characteristic D-shaped exit hole. Immature larvae can ] in their larval gallery, but can require an additional summer of feeding before overwintering again and emerging as adults the following spring.<ref name="USDA-APHIS-ARS-FS"/> Eggs are deposited between bark crevices, flakes, or cracks and hatch about two weeks later. Eggs are approximately {{cvt|0.6|to|1.0|mm|in|2|sp=us}} in diameter, and are initially white, but later turn reddish-brown if fertile.<ref name="Herms et al. 2013"/><ref name=" USDA-APHIS-ARS-FS"/> After hatching, larvae chew through the bark to the inner ], ], and outer ] where they feed and develop.<ref name="Poland">{{Cite journal |last1=Poland |first1=Therese. M |last2=Chen |first2=Tigen |last3=Jennifer |first3=Koch |last4=Pureswaran |first4=Deepa |title=Review of the emerald ash borer (Coleoptera: Buprestidae), life history, mating behaviours, host plant selection, and host resistance |journal=The Canadian Entomologist |date=December 2014 |volume=147 |issue=3 |pages=252–262 |url=http://www.fs.fed.us/nrs/pubs/jrnl/2015/nrs_2015_poland_001.pdf |doi=10.4039/tce.2015.4 |s2cid=29265154 |archive-url=https://web.archive.org/web/20151223052652/http://www.fs.fed.us/nrs/pubs/jrnl/2015/nrs_2015_poland_001.pdf |archive-date=23 December 2015}}</ref> Emerald ash borer has four larval ]s. By feeding, larvae create long serpentine galleries. Fully mature fourth-instar larvae are {{cvt|26|to|32|mm|in|sp=us}} long.<ref name="USDA-APHIS-ARS-FS"/> In fall, mature fourth-instars excavate chambers about {{cvt|1.25|cm|in|sp=us}} into the sapwood or outer bark where they fold into a J-shape.<ref name="Poland"/> These J-shaped larvae shorten into prepupae and develop into pupae and adults the following spring. To exit the tree, adults chew holes from their chamber through the bark, which leaves a characteristic D-shaped exit hole. Immature larvae can ] in their larval gallery, but can require an additional summer of feeding before overwintering again and emerging as adults the following spring.<ref name="USDA-APHIS-ARS-FS"/> This two-year life cycle is more common in cool climates, such as ].<ref name="Valenta2016"/>
{|style="margin: 0 auto;"
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<gallery mode="packed" heights="100px">
==As an invasive species==
File:Eablarva.jpg|Larva
] killed by emerald ash borers]]
File:Eabpupa.jpg|Pupa removed from its pupal chamber.
Outside its native range, emerald ash borer is an ], that is highly destructive to ] in its ] range.<ref>{{cite web | title =Agrilus planipennis (insect) | work =Global Invasive Species Database | publisher =ISSG-IUCN | date =August 14, 2006 | url =http://www.issg.org/database/species/ecology.asp?si=722&fr=1&sts=sss&lang=EN | accessdate = August 28, 2013}}</ref> Prior to EAB being found in North America, very little was known about EAB in it's native range aside from a short description of life-history traits and taxonomic descriptions, which resulted in focused research on its biology in North America.<ref name="Herms et al. 2013"/> Since its accidental introduction into the United States and Canada in the 1990s and its subsequent detection in 2002 in ], it has since spread other parts of the North America.<ref>{{cite web | title =Initial county EAB detections in North America| publisher =USDA Cooperative Emerald Ash Borer Project | date =May 1, 2014 | url =http://www.emeraldashborer.info/files/MultiState_EABpos.pdf | accessdate = May 1, 2014}}</ref> It is suspected that it was introduced from overseas in shipping materials such as packing crates.<ref name="Cappaert et al. 2005">{{cite journal | last =Cappaert | first =D. | title =Emerald ash borer in North America: a research and regulatory challenge | journal =American Entomologist | volume =51 | pages =152–163 | date =Fall 2005 | url =http://www.treesearch.fs.fed.us/pubs/13648 | display-authors=etal}}</ref>
File:Eabexithole.jpg|Adults exit the tree from D-shaped holes.
File:EmeraldAshBorerdorsal.jpg|Dorsal view of adult with elytra and wings spread.
Image:Ventral adult eab.jpg|Underside of an adult emerald ash borer.
</gallery>


==Range==
===Invasiveness and spread===
]
Without factors that would normally suppress EAB populations in its native range (e.g., resistant trees, predators, and ]s), EAB populations can quickly rise to damaging levels.<ref name="Herms et al. 2013">{{cite journal|last=Herms|first=Daniel A.|author2=Deborah G. McCullough|title=Emerald Ash Borer Invasion of North America: History, Biology, Ecology, Impacts, and Management|journal=Annual Review of Entomology|date=October 9, 2013|volume=59|pages=13–30|url=http://www.annualreviews.org/doi/pdf/10.1146/annurev-ento-011613-162051|accessdate=21 May 2014|doi=10.1146/annurev-ento-011613-162051|pmid=24112110}}</ref> After initial infestation, all ash trees are expected to die in an area within 10 years without control measures.<ref name="Herms et al. 2013" /> Every North American ash species shows susceptibility to EAB as North American species planted in China also show high mortality due to EAB infestation, but some Chinese ash species show resistance.<ref>{{cite journal|last=Lui|first=Houping|title=Exploratory survey for the emerald ash borer, Agrilus planipennis (Coleoptera: Buprestidae), and its natural enemies in China.|journal=Great Lakes Entomologist|date=2003|volume=36|pages=191–204|url=http://www.ncrs.fs.fed.us/pubs/jrnl/2003/nc_2003_liu_001.pdf|accessdate=28 May 2014|display-authors=etal}}</ref><ref>{{cite journal|last=Rebek|first=E. J.|last2=Herms|first2=D. A. |last3=Smitley|first3=D. R.|title=Interspecific Variation in Resistance to Emerald Ash Borer (Coleoptera: Buprestidae) Among North American and Asian Ash (Fraxinus spp.)|journal=Environmental Entomology|date=2013|volume=37|issue=1|pages=242–246|url=http://www.oardc.ohio-state.edu/hermslab/images/Rebek_et_al_2008_Plant_Insect_Interact_Variation_in_Resistance_of_ash_to_EAB.pdf|pmid=18348816| display-authors=etal}}</ref>
]

The native range of the emerald ash borer is ] north-eastern Asia, which includes Russia, Mongolia, northern China, Japan, and Korea.<ref name=issg>{{cite web |title=''Agrilus planipennis'' (insect) |work=Global Invasive Species Database |publisher=ISSG-IUCN |date=August 14, 2006 |url=http://www.issg.org/database/species/ecology.asp?si=722&fr=1&sts=sss&lang=EN |access-date=August 28, 2013 |archive-date=March 4, 2016 |archive-url=https://web.archive.org/web/20160304060927/http://www.issg.org/database/species/ecology.asp?si=722&fr=1&sts=sss&lang=EN |url-status=dead }}</ref><ref name="Valenta2016"/>

The beetle is invasive in North America where it has a core population in ] and surrounding states and provinces. Populations are more scattered outside the core area, and the edges of its known distribution range north to ], south to northern ], west to ], and east to ].<ref name="USDA info">{{cite web |title=Emerald ash borer |publisher=USDA Forest Service |url=http://www.emeraldashborer.info |access-date=July 5, 2015}}</ref><ref>{{cite web |title=Emerald ash borer makes first appearance in Fredericton |url=https://www.cbc.ca/news/canada/new-brunswick/emerald-ash-borer-fredericton-1.5931610 |website=CBC }}</ref> Satellite populations also exist in Colorado and in the Pacific Northwest in ].<ref name="survey-DOA-EAB">{{cite web |access-date=2022-07-11 |date=2022-07-11 |website=]: Survey and Treatment Projects |url=https://www.oregon.gov/oda/programs/IPPM/SurveyTreatment/Pages/EmeraldAshBorer.aspx |title=Emerald Ash Borer}}</ref><ref name="2022-06-30-ODA">{{cite web |access-date=2022-07-11 |language=en, es |date=2022-07-11 |website=] News |url=https://odanews.wpengine.com/oregon-dad-spots-the-first-emerald-ash-borers-on-the-west-coast-during-summer-camp-pickup-in-forest-grove/ |title=Oregon dad spots the first emerald ash borers on the West Coast during summer camp pickup in Forest Grove}}</ref><ref>{{Cite web |title=Invasive beetle known for wiping out ash trees found in Oregon: "The most destructive and costliest forest pest ever to invade North America" |url=https://www.cbsnews.com/news/emerald-ash-borer-found-oregon-invasive/ |access-date=2022-07-13 |website=www.cbsnews.com |date=12 July 2022 |language=en-US}}</ref> In eastern Europe, a population was found in Moscow in 2003.<ref name="Valenta2016">{{cite journal |title=A new forest pest in Europe: a review of Emerald ash borer (''Agrilus planipennis'') invasion |author=Valenta, V. |display-authors=etal |year=2016 |journal=Journal of Applied Entomology |volume=141 |issue=7 |pages=507–526 |doi=10.1111/jen.12369 |s2cid=88827218}}</ref> From 2003 to 2016, this population has spread west towards the European Union at up to {{cvt|40|km|mi}} per year and is expected to reach ] between 2031 and 2036.<ref name="Thomas2016">{{cite journal |title=Biological Flora of the British Isles: ''Fraxinus excelsior'' |author=Peter A. Thomas |year=2016 |journal=Journal of Ecology |volume=104 |issue=4 |pages=1158–1209 |doi=10.1111/1365-2745.12566 |bibcode=2016JEcol.104.1158T |s2cid=86930831|doi-access=free }}</ref><ref>{{cite news |publisher=BBC |title=Ash tree set for extinction in Europe |date=23 March 2016 |url=https://www.bbc.co.uk/news/science-environment-35876621 |access-date=23 March 2016}}</ref><ref name="Valenta2016"/> Although not recorded from the European Union as of 2019, it has already spread to far eastern Ukraine from neighboring Russia.<ref>{{cite bioRxiv |author1=Marina J. Orlova-Bienkowskaja |author2=Alexander N. Drogvalenko |author3=Ilya A. Zabaluev |author4=Alexey S. Sazhnev |author5=Elena Yu. Peregudova |author6=Sergey G. Mazurov |author7=Evgenij V. Komarov |author8=Andrzej O. Bieńkowski |year=2019 |title=Bad and good news for ash trees in Europe: alien pest ''Agrilus planipennis'' has spread to the Ukraine and the south of European Russia, but does not kill ''Fraxinus excelsior'' in the forests |biorxiv=10.1101/689240}}</ref><ref>{{cite web |title=Emerald ash borer (''Agrilus planipennis'') |date=24 January 2017 |url=https://www.daera-ni.gov.uk/articles/emerald-ash-borer-agrilus-planipennis |publisher=] |access-date=22 July 2019}}</ref><ref>{{cite journal |title=Record of the Emerald Ash Borer (''Agrilus planipennis'') in Ukraine is Confirmed |journal=Insects |date=11 October 2019 |volume=10 |issue=10 |pages=338 |doi=10.3390/insects10100338 |doi-access=free |last1=Drogvalenko |last2=Orlova-Bienkowskaja |last3=Bieńkowski |pmid=31614614 |pmc=6835871}}</ref><ref>{{cite web |url=https://gd.eppo.int/reporting/article-6632 |title=Presence of ''Agrilus planipennis'' confirmed in Ukraine |access-date=31 December 2019 |date=2019 |publisher=EPPO}}</ref>

== Host plants==
In its native range, emerald ash borer is only a nuisance pest on native trees, as population densities typically do not reach levels lethal to healthy trees.<ref name="Wang et al. 2010">{{cite journal |last=Wang |first=Xiao-Yi |title=The biology and ecology of the emerald ash borer, ''Agrilus planipennis'', in China |journal=Journal of Insect Science |date=2010 |volume=10 |issue=128 |page=128 |url=|display-authors=etal |doi=10.1673/031.010.12801 |pmid=20879922 |pmc=3016904}}</ref> In China, it infests native '']'', ], and ]; in Japan it also infests ] and ].<ref name="Valenta2016"/>

Emerald ash borer primarily infest and can cause significant damage to ] including green ash ('']''), black ash ('']''), white ash ('']''), and blue ash ('']'') in North America.<ref name="Poland and McCullough 2006">{{cite journal |last1=Poland |first1=T. |last2=McCullough |first2=D. |title=Emerald ash borer: invasion of the urban forest and the threat to North America's ash resource |journal=Journal of Forestry |volume=104 |pages=118–124 |date=2006 |url=http://www.nrs.fs.fed.us/pubs/jrnl/2006/nc_2006_Poland_003.pdf |archive-url=https://web.archive.org/web/20111017034200/http://www.nrs.fs.fed.us/pubs/jrnl/2006/nc_2006_Poland_003.pdf|archive-date=17 October 2011}}</ref> In Europe, '']'' is the main ash species colonized, which is moderately resistant to emerald ash borer infestation.<ref name="Valenta2016"/><ref>{{cite journal | last1=Showalter | first1=David N. | last2=Saville | first2=Robert J. | last3=Orton | first3=Elizabeth S. | last4=Buggs | first4=Richard J. A. | last5=Bonello | first5=Pierluigi | last6=Brown | first6=James K. M. | title=Resistance of European ash (''Fraxinus excelsior'') saplings to larval feeding by the emerald ash borer (''Agrilus planipennis'') | journal=Plants, People, Planet | publisher=Wiley | volume=2 | issue=1 | date=2019-11-13 | issn=2572-2611 | doi=10.1002/ppp3.10077 | pages=41–46| s2cid=209588339 | doi-access=free }}</ref> Ash susceptibility can vary depending on the attractiveness of chemical ] to adults, or the ability of larvae to detoxify ] compounds.<ref name="Poland"/> Emerald ash borer has also been found infesting ] in North America, which is a non-ash host, but it is unclear whether the trees were healthy when first infested, or were already in decline because of drought.<ref name="Poland"/><ref>{{cite web |title=Emerald Ash Borer attacking White Fringe Tree |url=http://web.extension.illinois.edu/lmw/eb255/entry_9199/ |date=November 2, 2014 |url-status=dead |archive-url=https://web.archive.org/web/20150507135953/http://web.extension.illinois.edu/lmw/eb255/entry_9199/ |archive-date=May 7, 2015 |access-date=14 December 2014}}</ref> Another non-ash host has also been discovered, '']'', albeit in a lab setting.<ref>{{cite web |url=https://entomologytoday.org/2017/05/23/olive-tree-is-second-non-ash-species-found-vulnerable-to-emerald-ash-borer/ |title=Olive Tree is Second Non-Ash Species Found Vulnerable to Emerald Ash Borer |publisher=Entomology Today |date=2017-05-23 |access-date=2021-06-07}}</ref>

Adults prefer to lay eggs on open grown or stressed ash but readily lay eggs on healthy trees amongst other tree species. Ashes that grow in pure stands, whether naturally occurring or in landscaping, are more prone to attack than isolated trees or ones located in mixed forest stands. Ashes used in landscaping also tend to be subjected to higher amounts of environmental stresses including compacted soil, lack of moisture, heating effects from ], road salt, and pollution, which may also reduce their resistance to the borer. Furthermore, most ashes used in landscaping were produced from a handful of cultivars, resulting in low ].<ref name="Poland"/> Young trees with bark between {{cvt|1.5|mm|in|sp=us}} to {{cvt|5|mm|in|sp=us}} are preferred.<ref name="Valenta2016"/> Both males and females use leaf volatiles and ] in the bark to locate hosts.<ref name="Poland"/> Damage occurs in infested trees by larval feeding. The serpentine feeding galleries of the larvae disrupt the flow of nutrients and water, effectively ], thus killing the tree, as it is no longer able to transport sufficient water and nutrients to the leaves to survive. Girdled ashes will often attempt to regenerate through stump sprouting, and there is evidence that stressed trees may also generate higher than normal seed crops as an emergency measure.<ref name="Herms et al. 2013"/>

==Invasiveness==
] killed by emerald ash borers]]
] with bark stripped by woodpeckers feeding on emerald ash borers]]

Outside its native range, emerald ash borer is an ] that is highly destructive to ash trees in its ] range.<ref name=issg /> Before emerald ash borer was found in North America, very little was known about the insect in its native range aside from a short description of life-history traits and taxonomic descriptions, which resulted in focused research on its biology in North America.<ref name="Herms et al. 2013"/> The insect was first identified in ] (near ]<ref name="Cappaert et al. 2005" />), in 2002,<ref name="Cappaert et al. 2005" /> but it may have been in the U.S. since the late 1980s.<ref name="UScountydetections"/> It is suspected that it was introduced from overseas in shipping materials such as packing crates.<ref name="Cappaert et al. 2005">{{cite journal |last=Cappaert |first=D. |title=Emerald ash borer in North America: a research and regulatory challenge |journal=American Entomologist |volume=51 |issue=3 |pages=152–163 |date=Fall 2005 |url=http://www.treesearch.fs.fed.us/pubs/13648 |display-authors=etal |doi=10.1093/ae/51.3.152 |doi-access=free |access-date=2014-11-20 |archive-date=2016-05-03 |archive-url=https://web.archive.org/web/20160503172928/http://www.treesearch.fs.fed.us/pubs/13648 |url-status=dead }}</ref>

Without factors that would normally suppress emerald ash borer populations in its native range (e.g., resistant trees, predators, and ]s), populations can quickly rise to damaging levels.<ref name="Herms et al. 2013"/> After initial infestation, all ash trees are expected to die in an area within 10 years without control measures.<ref name="Herms et al. 2013" /> Every North American ash species has susceptibility to emerald ash borer, as North American species planted in China also have high mortality from infestations, but some Asian ash species are resistant, including ''], F. chinensis, ], F. mandshurica'', and '']''.<ref name="Kelly2020" >{{cite journal |title=Convergent molecular evolution among ash species resistant to the emerald ash borer |year=2020 |last1=Kelly |first1=Laura J. |last2=Plumb |first2=William J. |last3=Carey |first3=David W. |last4=Mason |first4=Mary E. |last5=Cooper |first5=Endymion D. |last6=Crowther |first6=William |last7=Whittemore |first7=Alan T. |last8=Rossiter |first8=Stephen J. |last9=Koch |first9=Jennifer L. |last10=Buggs |first10=Richard J. A. |journal=Nature Ecology & Evolution |volume=4 |issue=8 |pages=1116–1128 |doi=10.1038/s41559-020-1209-3 |pmid=32451426 |pmc=7610378 }}</ref><ref>{{cite journal |last=Liu |first=Houping |title=Exploratory survey for the emerald ash borer, ''Agrilus planipennis'' (Coleoptera: Buprestidae), and its natural enemies in China |journal=Great Lakes Entomologist |date=2003 |volume=36 |pages=191–204 |url=https://www.nrs.fs.fed.us/pubs/jrnl/2003/nc_2003_liu_001.pdf |access-date=28 May 2014 |display-authors=etal |archive-date=24 January 2022 |archive-url=https://web.archive.org/web/20220124163133/https://www.nrs.fs.fed.us/pubs/jrnl/2003/nc_2003_liu_001.pdf |url-status=dead }}</ref><ref>{{cite journal |last1=Rebek |first1=E. J. |last2=Herms |first2=D. A. |last3=Smitley |first3=D. R.|display-authors=etal |date=2013 |title=Interspecific variation in resistance to Emerald Ash Borer (Coleoptera: Buprestidae) among North American and Asian ash (''Fraxinus'' spp.) |url=http://www.oardc.ohio-state.edu/hermslab/images/Rebek_et_al_2008_Plant_Insect_Interact_Variation_in_Resistance_of_ash_to_EAB.pdf |journal=Environmental Entomology |volume=37 |issue=1 |pages=242–246 |doi=10.1603/0046-225X(2008)372.0.CO;2 |pmid=18348816 |archive-url=https://web.archive.org/web/20160304124315/http://www.oardc.ohio-state.edu/hermslab/images/Rebek_et_al_2008_Plant_Insect_Interact_Variation_in_Resistance_of_ash_to_EAB.pdf |archive-date=March 4, 2016 |doi-access=free}}</ref>

] and ] trees are preferred by emerald ash borer. ] is also killed rapidly but usually only after all green and black ash trees are eliminated. ] is known to exhibit a higher degree of resistance to emerald ash borer, which is believed to be caused by the high ] content in the leaves making the foliage unpalatable to the insect. While most Asian ashes have evolved this defense, it is absent from American species other than blue ash. Researchers have examined populations of so-called "lingering ash", trees that survived ash borer attack with little or no damage, as a means of grafting or breeding new, resistant stock. Many of these lingering ashes were found to have unusual phenotypes that may result in increased resistance. Aside from their higher tannin content, Asian ashes also employ natural defenses to repel, trap, and kill emerald ash borer larvae. Although studies of American ashes have suggested that they are capable of mustering similar defensive mechanisms, the trees do not appear to recognize when they are under attack.<ref name="Anulewicz, et al. 2007">{{cite journal |last1=Anulewicz |first1=Andrea C. |last2=McCullough |first2=Deborah G. |last3=Cappaert |first3=David L. |title=Emerald Ash Borer (''Agrilus planipennis'') Density and Canopy Dieback in Three North American Ash Species |journal=Arboriculture & Urban Forestry |volume=33 |issue=5 |pages=338–349 |date=September 2007 |doi=10.48044/jauf.2007.039|doi-access=free }}</ref> Many of the specialized predators and parasitoids that suppressed emerald ash borer in Asia were not present in North America. Predators and parasitoids native to North America do not sufficiently suppress emerald ash borer, so populations continue to grow. Birds such as woodpeckers feed on emerald ash borer larva, although the adult beetles have not been used by any American fauna as food.<ref name="Herms et al. 2013" /> Emerald ash borer populations can spread between {{cvt|2.5|to|20|km|mi}} per year.<ref name="Herms et al. 2013"/> It primarily spreads through flight or by transportation of ash bark containing products such as firewood or nursery stock, which allows it to reach new areas and create satellite populations outside of the main infestation.<ref name="Herms et al. 2013" /><ref name="Valenta2016"/>

Other factors can limit spread. Winter temperatures of approximately {{cvt|-38|°C|°F}} limit range expansion,<ref>{{cite journal |last=DeSantis |first=Ryan D. |title=Effects of climate on emerald ash borer mortality and the potential for ash survival in North America |journal=Agricultural and Forest Meteorology |date=April 21, 2013 |volume=178 |page=120 |doi=10.1016/j.agrformet.2013.04.015 |bibcode=2013AgFM..178..120D |url=http://www.elsevier.com/locate/agrformet |display-authors=etal}}</ref><ref>{{cite news |title=The Upside Of The Bitter Cold: It Kills Bugs That Kill Trees |newspaper=NPR |date=10 January 2014 |publisher=National Public Radio |url=https://www.npr.org/2014/01/10/261435111/the-upside-of-the-bitter-cold-it-kills-bugs-that-kill-trees |access-date=May 21, 2014 |last1=Schaper |first1=David}}</ref> and overwintering emerald ash borer survive down to average temperatures of {{cvt|-30|°C|°F}} because of antifreeze chemicals in the body and insulation provided by tree bark.<ref name="Valenta2016"/> Larvae can also survive high heat up to {{cvt|53|°C|°F}}. Conversely, much like ashes grown in the nursery trade, the population of emerald ash borer in North America is believed to have originated from a single group of insects from central China and also exhibits low genetic diversity.<ref name="Valenta2016"/>

North American predators and parasitoids can occasionally cause high emerald ash borer mortality, but generally offer only limited control. Mortality from native woodpeckers is variable. Parasitism by parasitoids such as '']'' can be high, but overall such control is generally low.<ref name="Herms et al. 2013"/>


The ]'s ] published a rule on December 14, 2020—to take effect one month later, January 14, 2021—ending all EAB quarantine activities in the ] due to ineffectiveness so far.<ref name="APHIS-relax-EAB" /><ref name="APHIS-relax-EAB-final-rule" /> Other means will be used instead, especially biological controls (see ] below).<ref name="APHIS-relax-EAB" /><ref name="APHIS-relax-EAB-final-rule" />
] and the ] trees are preferred by EAB. ] is also killed rapidly, but usually only after all green and black ash trees are eliminated. ] displays some resistance to the emerald ash borer by forming callous tissue around EAB ], but are eventually killed.<ref name="Anulewicz, et al. 2007">{{cite journal | last =Anulewicz | first =Andrea C. | last2 =McCullough | first2 =Deborah G. | last3 =Cappaert | first3 =David L. | title =Emerald Ash Borer (Agrilus planipennis) Density and Canopy Dieback in Three North American Ash Species | journal =Aboriculture & Urban Forestry | volume =33 | issue =5 | pages =338–349 | publisher =International Society of Aboriculture | date =September 2007 | url =http://link.springer.com/article/10.1007%2Fs10530-013-0543-7| doi =10.1007/s10530-013-0543-7 }}</ref> Many of the specialized predators and parasitoids that suppressed EAB populations in Asia were not present in North America. Predators and parasitoids native to North America do not sufficiently suppress EAB, so populations continue to grow.<ref name="Herms et al. 2013" /><ref name="Klooster et al. 2013">{{cite journal|last=Klooster|first=Wendy S.|last2=Herms|first2=Daniel A.|last3=Knight|first3=Kathleen S.|last4=Herms|first4=Catherine P.|last5=McCullough|first5=Deborah G.|last6=Smith|first6=Annemarie|last7=Gandhi|first7=Kamal J. K.|last8=Cardina|first8=John|title=Ash (Fraxinus spp.) mortality, regeneration, and seed bank dynamics in mixed hardwood forests following invasion by emerald ash borer (Agrilus planipennis)|journal=Biological Invasions|date=August 20, 2013|volume=16|issue=4|pages=859–873|url=http://www.kamal.gandhi.uga.edu/publications/Kloosteretal_2013_ash%20dynamics.pdf|doi=10.1007/s10530-013-0543-7| display-authors=etal}}</ref> EAB populations can spread {{convert|20|km|mile|abbr=on}} a year.<ref name="Herms et al. 2013"/> However, it primarily spreads longer distances by transport of firewood and other wood products that contain ash bark, which allows EAB to reach new areas and create satellite populations outside of the main infestation.<ref name="Herms et al. 2013" />


These insects have managed to eliminate close to 300,000 Ash trees in the National Capital Region in only nine years. This leaves only 80,000 ash trees left standing either due to luck or to some amount of resistance to the beetles. These forests used to have an extremely dense Ash population having 17-18 trees per Hectare now there are only 5-6 trees per Hectare. This illustrates extremely well the overall destructive power of the Emerald Ash Borer and the relevance to the everyday person. Something extremely important to note about this severe loss of Ash trees is the effect that it has on the ecosystem of that area. Swamplands that used to be home many Ash forest have now become shrublands, completely changing the ecosystem of that area permanently. The impact this has on the wildlife is extreme because of all the animals that used every part of the tree as refuge, such as birds in the foliage, small rodents amongst the roots, etc.<ref>{{Cite web |last=Crystal |first=Chen |date=September 28, 2022 |title=Ash Tree Update 2021 |url=https://www.nps.gov/articles/000/ash-tree-update-2021.htm}}</ref>
Other factors can limit its spread. Climate research suggests that EAB growth may be stemmed in areas too cold for the beetle to survive.<ref>{{cite journal|last=DeSantis|first=Ryan D.|title=Effects of climate on emerald ash borer mortality and the potential for ash survival in North America|journal=Agricultural and Forest Meteorology|date=April 21, 2013|volume=178|page=120|url=http://www.elsevier.com/locate/agrformet|display-authors=etal}}</ref><ref>{{cite web | title =The Upside Of The Bitter Cold: It Kills Bugs That Kill Trees | publisher = National Public Radio | url = http://www.npr.org/2014/01/10/261435111/the-upside-of-the-bitter-cold-it-kills-bugs-that-kill-trees | accessdate = May 21, 2014}}</ref> North American predators and parasitoids can occasionally cause high EAB mortality, but generally offer only limited control. Mortality due to native woodpeckers is variable. Parasitism by parasitoids such as '']'' can be high, but overall such control is generally low.<ref name="Herms et al. 2013"/>


===Environmental and economic impacts=== ===Environmental and economic impacts===
EAB threatens the entire North American '']'' genus. It has killed at least tens of millions of ash trees so far and threatens to kill most of the 8.7 billion ash trees throughout North America.<ref name="USDA info">{{cite web | title =Emerald ash borer | publisher =USDA Forest Service | url =http://www.emeraldashborer.info | accessdate = April 15, 2014}}</ref> Emerald ash borer kills young trees several years before reaching their seeding age of 10 years.<ref name="Klooster et al. 2007">{{cite journal | last =Klooster | first =Wendy S. | title =Ash (Fraxinus spp.) mortality, regeneration, and seed bank dynamics in mixed hardwood forests following invasion by emerald ash borer (Agrilus planipennis) | journal =Biological Invasions | volume =16 | issue =4 | pages =859–873 | date =April 2014 | url =http://link.springer.com/article/10.1007/s10530-013-0543-7 | doi=10.1007/s10530-013-0543-7|display-authors=etal}}</ref> The loss of ash from an ecosystem can result in increased numbers of invasive plants, changes in soil nutrients, and effects on species that feed on ash.<ref name="Herms et al. 2013" />


Emerald ash borer threatens the entire North American genus '']''. It has killed tens of millions of ash trees so far and threatens to kill most of the 8.7 billion ash trees throughout North America.<ref name="USDA info"/> Emerald ash borer kills young trees several years before reaching their seeding age of 10 years.<ref name="Herms et al. 2013" /> In both North America and Europe, the loss of ash from an ecosystem can result in increased numbers of invasive plants, changes in soil nutrients, and effects on species that feed on ash.<ref name="Valenta2016"/>
Damage and efforts to control the spread of EAB have affected businesses that sell ash trees or wood products, property owners, and local or state governments.<ref name="Herms et al. 2013" /> Quarantines can limit the transport of ash trees and products. Economic impacts are especially high for urban and residential areas due to treatment or removal costs and decreased land value from dying trees. Costs for managing these trees can fall upon homeowners or local municipalities. For municipalities, removing large numbers of dead or infested trees at once is costly, so slowing down the rate at which trees die through removing known infested trees and treating trees with insecticides can allow local governments more time to plan, remove, and replace trees that would eventually die. This strategy saves money as it would cost $10.7 billion in urban areas of 25 states between 2009–2019, while removing and replacing all ash trees in these same areas at once would cost $25 billion.<ref name="Kovacs, et al. 2010">{{cite journal | last =Kovacs | first =K. F. | title =Cost of potential emerald ash borer damage in U.S. communities, 2009-2019. | journal =Ecological Economics | volume =69 | issue =3 | pages =569–578 | date =September 2009 | url =http://m.mi.gov/documents/mda/EAB_-_Ecol_Econ_-_reprint_325348_7.pdf | doi=10.1016/j.ecolecon.2009.09.004|display-authors=etal}}</ref> Some urban areas such as ], Minnesota, have large amounts of ash with slightly more than 20% of their urban forest as ash.<ref>{{cite web | title =Emerald Ash Borer (EAB) is in Minneapolis| publisher =Minneapolis Park and Recreation Board | url =http://www.minneapolisparks.org/default.asp?PageID=1059 | accessdate = August 29, 2013}}</ref>


Damage and efforts to control the spread of emerald ash borer have affected businesses that sell ash trees or wood products, property owners, and local or state governments.<ref name="Herms et al. 2013" /> Quarantines can limit the transport of ash trees and products, but economic impacts are especially high for urban and residential areas because of treatment or removal costs and decreased land value from dying trees.<ref name="SLAM">{{cite journal |last1=McCullough |first1=D.G. |title=Evaluation of potential strategies to SLow Ash Mortality (SLAM) caused by emerald ash borer (''Agrilus planipennis''): SLAM in an urban forest |journal=International Journal of Pest Management |volume=58 |pages=9–23 |year=2012 |url=http://www.actrees.org/wp-content/uploads/2012/12/Urban-SLAM-pdf.pdf |doi=10.1080/09670874.2011.637138 |s2cid=62821195 |display-authors=etal |access-date=2016-02-10 |archive-date=2021-07-25 |archive-url=https://web.archive.org/web/20210725054945/http://www.actrees.org/wp-content/uploads/2012/12/Urban-SLAM-pdf.pdf |url-status=dead }}</ref> Costs for managing these trees can fall upon homeowners or local municipalities. For municipalities, removing large numbers of dead or infested trees at once is costly, so slowing down the rate at which trees die through removing known infested trees and treating trees with insecticides can allow local governments more time to plan, remove, and replace trees that would eventually die. This strategy saves money as it would cost $10.7 billion in urban areas of 25 states over 10 years, while removing and replacing all ash trees in these same areas at once would cost $25 billion<ref name="SLAM"/><ref name="Kovacs, et al. 2010">{{cite journal |last=Kovacs |first=K. F.|display-authors=etal |date=September 2009 |title=Cost of potential emerald ash borer damage in U.S. communities, 2009-2019. |url=http://m.mi.gov/documents/mda/EAB_-_Ecol_Econ_-_reprint_325348_7.pdf |url-status=dead |journal=Ecological Economics |volume=69 |issue=3 |pages=569–578 |doi=10.1016/j.ecolecon.2009.09.004 |archive-url=https://web.archive.org/web/20140407100616/http://m.mi.gov/documents/mda/EAB_-_Ecol_Econ_-_reprint_325348_7.pdf |archive-date=April 7, 2014}}</ref> (with another estimate putting the removal alone at $20–60 billion).<ref name="Cappaert et al. 2005" /> Some urban areas such as ] have large amounts of ash with slightly more than 20% of their ] as ash.<ref>{{cite web |title=Emerald Ash Borer (EAB) is in Minneapolis |publisher=Minneapolis Park and Recreation Board |url=http://www.minneapolisparks.org/default.asp?PageID=1059 |access-date=August 29, 2013 |archive-url=https://web.archive.org/web/20130808004843/http://minneapolisparks.org/default.asp?PageID=1059 |archive-date=August 8, 2013 |url-status=dead}}</ref>
===Monitoring and management===
In areas where EAB has not yet been detected, surveys are used to monitor for new infestations. Visual surveys are used to find ash trees displaying symptoms of EAB damage and colored traps attractive to EAB are hung in trees as part of a monitoring program. Sometimes trees are also girdled to act as a trap tree by attracting egg-laying female EAB in the spring and debarking the trees in the fall to search for larvae.<ref name="Herms et al. 2013" /> If detected, the area is typically placed under a quarantine to prevent infested wood material from causing new infestations.<ref>{{cite web| title =Initial county EAB detections in North America | publisher =USDA Forest Service | date =August 14, 2006 | url =http://www.emeraldashborer.info/files/MultiState_EABpos.pdf | accessdate = April 15, 2014}}</ref> Further control measures are then taken within the area to slow population growth by reducing EAB numbers, preventing them from reaching reproductive maturity and dispersing, and reducing the abundance of ash trees.<ref name="Herms et al. 2013" />
]


===Monitoring===
Government agencies in both the USA and Canada have utilized a native species of wasp, '']'', as a means of detecting areas to which EAB has spread. The females of these wasps hunt beetles in the same family as EAB and will hunt EAB if it is present. The wasps stun the beetles and carry them back to their burrows in the ground where they are stored until the wasps’ eggs hatch and the wasp larvae feed on the beetles. Volunteers catch the wasps as they return to their burrows carrying the beetles to determine whether any of the catch consists of EAB. If it does, the agencies running the program may institute quarantine measures. This methodology is known as biological surveillance, as opposed to biological control, because it does not appear that the wasps have a significant negative impact on EAB populations.<ref>{{cite journal|last=Careless|first=Philip|last2=Marhsall|first2=Stephen. A.|last3=Gill|first3=Bruce D.|title=The use of ''Cerceris fumipennis'' (Hymenoptera: Crabronidae) for surveying and monitoring emerald ash borer (Coleoptera: Buprestidae) infestations in eastern North America|journal=Canadian Entomologist|date=February 2014|volume=146|pages=90–105|url=http://dx.doi.org/10.4039/tce.2013.53|doi=10.4039/tce.2013.53|display-authors=etal}}</ref>
In areas where emerald ash borer has not yet been detected, surveys are used to monitor for new infestations. Visual surveys are used to find ash trees displaying emerald ash borer damage, and traps with colors attractive to emerald ash borer, such as purple or green, are hung in trees as part of a monitoring program.<ref name="Herms et al. 2013" /> These traps can also have volatile ] applied to them that attract primarily males.<ref name="Poland"/>


]
====Tree removal and replacement====

In urban areas, trees are often removed once an infestation is found to reduce EAB population densities and the likelihood of further spread. Urban ash are typically replaced with non-ash species such as maple, oak, or linden to limit food sources for EAB.<ref>{{cite web| title =Ash replacement information | publisher =USDA Forest Service | url =http://www.emeraldashborer.info/replacement.cfm | accessdate = July 15, 2014}}</ref> In rural areas, trees can be harvested for lumber or firewood to reduce ash stand density, but quarantines may apply, especially in areas where the material could be infested.<ref>{{cite web|title=SLAM: SLow Ash Mortality | url=http://www.slameab.info/}}</ref>
Sometimes trees are girdled to act as trap trees to monitor for emerald ash borer. The stressed tree attracts egg-laying females in the spring, and trees can be debarked in the fall to search for larvae.<ref name="Herms et al. 2013" /> If detected, an area is often placed under a quarantine to prevent infested wood material from causing new infestations.<ref name="UScountydetections"/><ref name="Herms et al. 2013" /> Further control measures are then taken within the area to slow population growth by reducing beetle numbers, preventing them from reaching reproductive maturity and dispersing, and reducing the abundance of ash trees.<ref name="Herms et al. 2013" />

Government agencies in both the U.S. and Canada have utilized a native species of parasitoid wasp, '']'', as a means of detecting areas to which emerald ash borer has spread. The females of these wasps hunt other ]s and emerald ash borer if it is present. The wasps stun the beetles and carry them back to their burrows in the ground where they are stored until the wasps’ eggs hatch and the wasp larvae feed on the beetles. Volunteers catch the wasps as they return to their burrows carrying the beetles to determine whether emerald ash borer is present. This methodology is known as biological surveillance, as opposed to biological control, because it does not appear that the wasps have a significant negative impact on emerald ash borer populations.<ref>{{cite journal |last1=Careless |first1=Philip |last2=Marshall |first2=Stephen. A. |last3=Gill |first3=Bruce D. |title=The use of ''Cerceris fumipennis'' (Hymenoptera: Crabronidae) for surveying and monitoring emerald ash borer (Coleoptera: Buprestidae) infestations in eastern North America |journal=Canadian Entomologist |date=February 2014 |volume=146 |pages=90–105 |doi=10.4039/tce.2013.53 |s2cid=83548128 |display-authors=etal}}</ref>

===Management===
In areas where emerald ash borer is non-native and invasive, quarantines, infested tree removal, insecticides, and biological control are used to reduce damage to ash trees.

====Quarantine and tree removal====
Once an infestation is detected, quarantines are typically imposed by state, or previously, national government agencies disallowing transport of ash firewood or live plants outside of these areas without permits indicating the material has been inspected or treated (i.e., heat treatment or wood chipping) to ensure no live emerald ash borer are present in the bark and phloem.<ref name="UScountydetections">{{cite web |title=Initial County EAB detections in North America |url=http://www.emeraldashborer.info/documents/MultiState_EABpos.pdf |publisher=USDA |access-date=28 January 2017}}</ref><ref>{{cite web |title=Moving Firewood |url=http://www.emeraldashborer.info/moving-firewood.php |publisher=USDA |access-date=28 January 2017 |archive-date=12 September 2021 |archive-url=https://web.archive.org/web/20210912141032/http://www.emeraldashborer.info/moving-firewood.php |url-status=dead }}</ref> In urban areas, trees are often removed once an infestation is found to reduce emerald ash borer population densities and the likelihood of further spread. Urban ash are typically replaced with non-ash species such as maple, oak, or linden to limit food sources.<ref>{{cite web |title=Ash replacement information |publisher=USDA Forest Service |url=http://www.emeraldashborer.info/replacement.cfm |access-date=July 15, 2014 |archive-date=January 26, 2016 |archive-url=https://web.archive.org/web/20160126094154/http://www.emeraldashborer.info/replacement.cfm |url-status=dead }}</ref> In rural areas, trees can be harvested for lumber or firewood to reduce ash stand density, but quarantines may apply for this material, especially in areas where the material could be infested.<ref>{{cite web |title=SLAM: SLow Ash Mortality |url=http://www.slameab.info/ |url-status=dead |archive-url=https://web.archive.org/web/20150302221108/http://www.slameab.info/ |archive-date=March 2, 2015}}</ref>

] specialists suggest selecting uncommon species to replace removed ashes in the landscape.<ref>{{Cite web |url=http://www2.ca.uky.edu/agcomm/pubs/ID/ID241/ID241.pdf |title=After Your Ash Has Died: Making an Informed Decision on What to Replant |website=extension.ca.uky.edu}}</ref> Previous generations created ]s by planting ash trees in an overabundance, a factor in the extent of the devastation caused by the emerald ash borer. Favoring instead a diversity in species helps keep urban forests healthy. ] scientists suggest choosing monotypic species such as the ], ], ], ], ], ], and ].


====Insecticides==== ====Insecticides====
Insecticides are typically only recommended in urban areas with high value trees near an infestation.<ref name="NCIPMC Bulletin">{{Citation | last =Herms | first =Daniel A. | last2 =McCullough | first2 =Deborah G. | last3 =Smitley | first3 =David R. | last4 =Sadof | first4 =Clifford S. | last5 =Williamson | first5 =R. Chris | last6 =Nixon | first6 =Phillip L. | title =Insecticide Options for Protecting Ash Trees from Emerald Ash Borer | journal = North Central IPM Center Bulletin | publisher =North Central IPM Center | date =June 2009 | pages =12 | url = http://www.emeraldashborer.info/files/multistate_eab_insecticide_fact_sheet.pdf | accessdate = August 30, 2013}}</ref> Insecticides with active ingredients such as ], ], and ] are currently recommended since they are systemic (i.e., incorporated into the tree) and remain effective for one to three years depending on the product.<ref name="Herms et al. 2013" /><ref name="NCIPMC Bulletin"/><ref name="FAQ">{{Citation | last =Hahn | first =Jeffrey | last2 =Herms | first2 =Daniel A. | last3 =McCullough | first3 =Deborah G. | title =Frequently Asked Questions Regarding Potential Side Effects of Systemic Insecticides Used to Control Emerald Ash Borer | publisher =www.emeraldashborer.info | date =February 2011 | url =http://emeraldashborer.info/files/Potential_Side_Effects_of_EAB_Insecticides_FAQ.pdf | accessdate = August 30, 2013}}</ref> Ash trees are primarily treated by direct injection into the tree or soil drench. Some insecticides cannot be applied by homeowners and must be applied by licensed applicators. Initially, tree injections will not compromise tree health, but over many years drilling and chemical wounds will compromise the tree's health.<ref>{{cite journal | last =Doccola | first =Joseph J. | last2 =Smitley | first2 =David R. | last3 =Davis | first3 =Terrance W. | last4 =Aiken | first4 =John J. | last5 =Wild | first5 =Peter M. | title =Tree Wound Responses Following Systemic Insecticide Trunk Injection Treatments in Green Ash (Fraxinus pennsylvanica Marsh.) as Determined by Destructive Autopsy | journal =Aboriculture & Urban Forestry | volume =37 | issue =1 | pages =6–12 | publisher =International Society of Arboriculture | date =January 2011 | url =http://auf.isa-arbor.com/request.asp?JournalID=1&ArticleID=3179&Type=2 }}</ref> Damage from EAB can continue to increase over time even with insecticide applications.<ref name="Herms et al. 2013" /> Insecticide treatments are not feasible for large forested areas outside of urban areas.<ref name="Herms et al. 2013" />


]
====Biological control====
The native range of EAB in Asia was surveyed for ] species that parasitize EAB and do not attack other insect species in the hope they would suppress EAB populations when released in North America.<ref name="APHIS">{{cite journal |last1=Bauer |first1=L.S. |last2=Liu|first2=H-P |last3=Miller|first3= D.|last4=Gould |first4=J.|year=2008 |title=Developing a classical biological control program for Agrilus planipennis (Coleoptera: Buprestidae), an invasive ash pest in North America |journal=Newsletter of the Michigan Entomological Society |publisher= |volume=53 |issue=3&4|pages=38–39|url=http://www.nrs.fs.fed.us/pubs/jrnl/2008/nrs_2008_bauer_002.pdf }}</ref> Three species imported from China were approved for release by the ] in 2007 and in Canada in 2013: '']'', '']'', and '']'', while '']'' was approved for release in 2015.<ref>{{Cite web|url=http://www.nrs.fs.fed.us/disturbance/invasive_species/eab/control_management/biological_control/|title=Biological Control of the Emerald Ash Borer|publisher=United States Department of Agriculture Forest Service}}</ref><ref name="Bauer2015">{{cite journal | last =Bauer | first =Leah S. | last2 =Duan | first2 =Jian J. | last3 =Gould | first3 =Juli R. | last4 =van Driesche | first4 =Roy| title =Progress in the classical biological control of ''Agrilus planipennis'' Fairmaire (Coleoptera:Bupresitdae) in North America | journal =The Canadian Entomologist | volume =147 | pages =300–317 | date =March 8, 2015 | url =http://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=9694843&fileId=S0008347X15000188 | doi=10.4039/tce.2015.18|display-authors=etal}}</ref> Excluding ''Spathius galinae'', which has only recently been released, the other three species have been documented parasitizing EAB larvae one year after release, indicating that they survived the winter, but establishment varied among species and locations.<ref name="Bauer2015"></ref> ''Tetrastichus planipennisi'' and ''Oobius agrili'' established and have had increasing populations in Michigan since 2008; ''Spathius agrili'' has had lower establishment success in North America, which could be due to a lack of available EAB larvae at the time of adult emergence in spring, limited cold tolerance, and better suitability to regions of North America below the 40th parallel.<ref name="Bauer2015"></ref>


Insecticides with active ingredients such as ], ], ], and ] are currently used. Dinotefuran and imidacloprid are systemic (i.e., incorporated into the tree) and remain effective for one to three years depending on the product.<ref name="Herms et al. 2013" /><ref name="NCIPMC Bulletin"/><ref name="FAQ">{{Citation |last1=Hahn |first1=Jeffrey |last2=Herms |first2=Daniel A. |last3=McCullough |first3=Deborah G. |title=Frequently Asked Questions Regarding Potential Side Effects of Systemic Insecticides Used to Control Emerald Ash Borer |publisher=www.emeraldashborer.info |date=February 2011 |url=http://emeraldashborer.info/files/Potential_Side_Effects_of_EAB_Insecticides_FAQ.pdf |access-date=August 30, 2013 |archive-date=July 14, 2015 |archive-url=https://web.archive.org/web/20150714223037/http://emeraldashborer.info/files/Potential_Side_Effects_of_EAB_Insecticides_FAQ.pdf |url-status=dead }}</ref> Insecticides are typically only considered a viable option in urban areas with high value trees near an infestation.<ref name="NCIPMC Bulletin">{{Citation |last1=Herms |first1=Daniel A. |last2=McCullough |first2=Deborah G. |last3=Smitley |first3=David R. |last4=Sadof |first4=Clifford S. |last5=Williamson |first5=R. Chris |last6=Nixon |first6=Phillip L. |title=Insecticide Options for Protecting Ash Trees from Emerald Ash Borer |journal=North Central IPM Center Bulletin |date=June 2009 |pages=12 |url=http://www.emeraldashborer.info/files/multistate_eab_insecticide_fact_sheet.pdf |access-date=August 30, 2013 |archive-date=January 26, 2016 |archive-url=https://web.archive.org/web/20160126222133/http://www.emeraldashborer.info/files/multistate_EAB_Insecticide_Fact_Sheet.pdf |url-status=dead }}</ref> Ash trees are primarily treated by direct injection into the tree or soil drench. Some insecticides cannot be applied by homeowners and must be applied by licensed applicators. Damage from emerald ash borer can continue to increase over time even with insecticide applications.<ref name="Herms et al. 2013" /> Insecticide treatments are not feasible for large forested areas outside of urban areas.<ref name="Herms et al. 2013" />
The USDA is also assessing the application of '']'', an insect fungal ], for controlling EAB in conjunction with parasitoid wasps.<ref name="ScienceDaily">{{cite web | title = Biocontrol: Fungus and Wasps Released to Control Emerald Ash Borer | work = Science News | publisher = Science Daily | date = May 2, 2011 | url = http://www.sciencedaily.com/releases/2011/04/110426111415.htm | accessdate = August 30, 2013}}</ref>

====Biological control{{anchor|biocontrol}}====
] wasp used as a ] agent]]

The native range of emerald ash borer in Asia was surveyed for parasitoid species that parasitize emerald ash borer and do not attack other insect species in the hope they would suppress populations when released in North America.<ref name="APHIS">{{cite journal |last1=Bauer |first1=L.S. |last2=Liu |first2=H-P |last3=Miller |first3=D. |last4=Gould |first4=J. |year=2008 |title=Developing a classical biological control program for ''Agrilus planipennis'' (Coleoptera: Buprestidae), an invasive ash pest in North America |journal=Newsletter of the Michigan Entomological Society |volume=53 |issue=3&4 |pages=38–39 |url=http://www.nrs.fs.fed.us/pubs/jrnl/2008/nrs_2008_bauer_002.pdf |access-date=2014-08-25 |archive-date=2011-10-04 |archive-url=https://web.archive.org/web/20111004090830/http://www.nrs.fs.fed.us/pubs/jrnl/2008/nrs_2008_bauer_002.pdf |url-status=dead }}</ref> Three species imported from China were approved for release by the ] in 2007 and in Canada in 2013: '']'', '']'', and '']'', while '']'' was approved for release in 2015.<ref>{{Cite web |url=http://www.nrs.fs.fed.us/disturbance/invasive_species/eab/control_management/biological_control/ |title=Biological Control of the Emerald Ash Borer |publisher=United States Department of Agriculture Forest Service |access-date=2014-08-25 |archive-date=2021-09-15 |archive-url=https://web.archive.org/web/20210915160723/https://www.nrs.fs.fed.us/disturbance/invasive_species/eab/control_management/biological_control/ |url-status=dead }}</ref><ref name="Bauer2015">{{cite journal |last1=Bauer |first1=Leah S. |last2=Duan |first2=Jian J. |last3=Gould |first3=Juli R. |last4=van Driesche |first4=Roy|display-authors=etal |date=March 8, 2015 |title=Progress in the classical biological control of ''Agrilus planipennis'' Fairmaire (Coleoptera: Buprestidae) in North America |journal=] |volume=147 |issue=3 |pages=300–317 |doi=10.4039/tce.2015.18 |s2cid=82909547}}</ref> Excluding ''Spathius galinae'', which has only recently been released, the other three species have been documented parasitizing emerald ash borer larvae one year after release, indicating that they survived the winter, but establishment varied among species and locations.<ref name="Bauer2015"/> ''Tetrastichus planipennisi'' and ''Oobius agrili'' established and have had increasing populations in Michigan since 2008; ''Spathius agrili'' has had lower establishment success in North America, which could be caused by a lack of available emerald ash borer larvae at the time of adult emergence in spring, limited cold tolerance, and better suitability to regions of North America below the 40th parallel.<ref name="Bauer2015"/>

The USDA is also assessing the application of '']'', an insect fungal ], for controlling emerald ash borer in conjunction with parasitoid wasps.<ref name="ScienceDaily">{{cite web |title=Biocontrol: Fungus and Wasps Released to Control Emerald Ash Borer |work=Science News |publisher=Science Daily |date=May 2, 2011 |url=https://www.sciencedaily.com/releases/2011/04/110426111415.htm |access-date=August 30, 2013}}</ref>


==See also== ==See also==
{{Portal|Insects}} {{Portal|Insects}}
* ] *]
* ] *]
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==References== ==References==
{{Reflist|2}} {{Reflist|30em|refs=
<ref name="APHIS-relax-EAB">{{cite web |title=APHIS Changes Approach to Fight Emerald Ash Borer EAB |website=]'s Phytosanitary Alert System |date=2020-12-14 |url=https://www.pestalerts.org/official-pest-report/aphis-changes-approach-fight-emerald-ash-borer-eab |access-date=2020-12-21}}</ref>
<ref name="APHIS-relax-EAB-final-rule">{{cite web |url=http://public-inspection.federalregister.gov/2020-26734.pdf |title=Removal of Emerald Ash Borer Domestic Quarantine Regulations |date=2020-12-15 |website=] |author=]'s ]}}</ref>
}}


==External links== ==External links==
{{Commons category|Emerald ash borer}} {{Commons category|Agrilus planipennis}}
{{wikispecies|Agrilus planipennis}} {{Wikispecies|Agrilus planipennis}}
* <!-- * -->
*, Canadian Food Inspection Agency
*
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*, National Invasive Species Information Center, ]. Lists general information and resources for Emerald Ash Borer.
*
*{{Internet Archive short film|id=gov.usda.aphis.green.menace|name=Emerald Ash Borer: The Green Menace}}
* PDF map
* , National Invasive Species Information Center, ]. Lists general information and resources for Emerald Ash Borer.
* {{Internet Archive short film|id=gov.usda.aphis.green.menace|name=Emerald Ash Borer: The Green Menace}}


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Latest revision as of 23:32, 4 November 2024

Species of beetle

Emerald ash borer
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Coleoptera
Family: Buprestidae
Genus: Agrilus
Species: A. planipennis
Binomial name
Agrilus planipennis
Fairmaire, 1888
Synonyms
  • Agrilus feretrius Obenberger
  • Agrilus marcopoli Obenberger

The emerald ash borer (Agrilus planipennis), also known by the acronym EAB, is a green buprestid or jewel beetle native to north-eastern Asia that feeds on ash species (Fraxinus spp.). Females lay eggs in bark crevices on ash trees, and larvae feed underneath the bark of ash trees to emerge as adults in one to two years. In its native range, it is typically found at low densities and does not cause significant damage to trees native to the area. Outside its native range, it is an invasive species and is highly destructive to ash trees native to Europe and North America. Before it was found in North America, very little was known about the emerald ash borer in its native range; this has resulted in much of the research on its biology being focused in North America. Local governments in North America are attempting to control it by monitoring its spread, diversifying tree species, and through the use of insecticides and biological control.

History

French priest and naturalist Armand David collected a specimen of the species during one of his trips through Imperial China in the 1860s and 1870s. He found the beetle in Beijing and sent it to France, where the first brief description of Agrilus planipennis by the entomologist Léon Fairmaire was published in the Revue d'Entomologie in 1888. Unaware of Fairmaire's description, a separate description naming the species as Agrilus marcopoli was published in 1930 by Jan Obenberger.

Identification

Adult beetles are typically bright metallic green and about 8.5 mm (0.33 in) long and 1.6 mm (0.063 in) wide. Elytra are typically a darker green, but can also have copper hues. Emerald ash borer is the only North American species of Agrilus with a bright red upper abdomen when viewed with the wings and elytra spread. The species also has a small spine found at the tip of the abdomen and serrate antennae that begin at the fourth antennal segment. They leave tracks in the trees they damage below the bark that are sometimes visible. Adult beetles of other species can often be misidentified by the public.

Life cycle

The emerald ash borer life cycle can occur over one or two years depending on the time of year of oviposition, the health of the tree, and temperature.

After 400–500 accumulated degree-days above 10 °C (50 °F), adults begin to emerge from trees in late spring, and peak emergence occurs around 1,000 degree-days. After emergence, adults feed for one week on ash leaves in the canopy before mating, but cause little defoliation in the process. Males hover around trees, locate females by visual cues, and drop directly onto the female to mate. Mating can last 50 minutes, and females may mate with multiple males over their lifespan. A typical female can live around six weeks and lay approximately 40–70 eggs, but females that live longer can lay up to 200 eggs.

Eggs are deposited between bark crevices, flakes, or cracks and hatch about two weeks later. Eggs are approximately 0.6 to 1.0 mm (0.02 to 0.04 in) in diameter, and are initially white, but later turn reddish-brown if fertile. After hatching, larvae chew through the bark to the inner phloem, cambium, and outer xylem where they feed and develop. Emerald ash borer has four larval instars. By feeding, larvae create long serpentine galleries. Fully mature fourth-instar larvae are 26 to 32 mm (1.0 to 1.3 in) long. In fall, mature fourth-instars excavate chambers about 1.25 cm (0.49 in) into the sapwood or outer bark where they fold into a J-shape. These J-shaped larvae shorten into prepupae and develop into pupae and adults the following spring. To exit the tree, adults chew holes from their chamber through the bark, which leaves a characteristic D-shaped exit hole. Immature larvae can overwinter in their larval gallery, but can require an additional summer of feeding before overwintering again and emerging as adults the following spring. This two-year life cycle is more common in cool climates, such as European Russia.

  • Larva Larva
  • Pupa removed from its pupal chamber. Pupa removed from its pupal chamber.
  • Adults exit the tree from D-shaped holes. Adults exit the tree from D-shaped holes.
  • Dorsal view of adult with elytra and wings spread. Dorsal view of adult with elytra and wings spread.
  • Underside of an adult emerald ash borer. Underside of an adult emerald ash borer.

Range

Native range of emerald ash borer in eastern Asia and introduced range in European Russia as of 2013
Map of US counties infested with emerald ash borer as of July 2024.

The native range of the emerald ash borer is temperate north-eastern Asia, which includes Russia, Mongolia, northern China, Japan, and Korea.

The beetle is invasive in North America where it has a core population in Michigan and surrounding states and provinces. Populations are more scattered outside the core area, and the edges of its known distribution range north to Ontario, south to northern Louisiana, west to Nebraska, and east to New Brunswick. Satellite populations also exist in Colorado and in the Pacific Northwest in Oregon. In eastern Europe, a population was found in Moscow in 2003. From 2003 to 2016, this population has spread west towards the European Union at up to 40 km (25 mi) per year and is expected to reach central Europe between 2031 and 2036. Although not recorded from the European Union as of 2019, it has already spread to far eastern Ukraine from neighboring Russia.

Host plants

In its native range, emerald ash borer is only a nuisance pest on native trees, as population densities typically do not reach levels lethal to healthy trees. In China, it infests native Fraxinus chinensis, F. mandshurica, and F. rhynchophylla; in Japan it also infests F. japonica and F. lanuginosa.

Emerald ash borer primarily infest and can cause significant damage to ash species including green ash (F. pennsylvanica), black ash (F. nigra), white ash (F. americana), and blue ash (F. quadrangulata) in North America. In Europe, F. excelsior is the main ash species colonized, which is moderately resistant to emerald ash borer infestation. Ash susceptibility can vary depending on the attractiveness of chemical volatiles to adults, or the ability of larvae to detoxify phenolic compounds. Emerald ash borer has also been found infesting white fringe tree in North America, which is a non-ash host, but it is unclear whether the trees were healthy when first infested, or were already in decline because of drought. Another non-ash host has also been discovered, Olea europaea, albeit in a lab setting.

Adults prefer to lay eggs on open grown or stressed ash but readily lay eggs on healthy trees amongst other tree species. Ashes that grow in pure stands, whether naturally occurring or in landscaping, are more prone to attack than isolated trees or ones located in mixed forest stands. Ashes used in landscaping also tend to be subjected to higher amounts of environmental stresses including compacted soil, lack of moisture, heating effects from urban islands, road salt, and pollution, which may also reduce their resistance to the borer. Furthermore, most ashes used in landscaping were produced from a handful of cultivars, resulting in low genetic diversity. Young trees with bark between 1.5 mm (0.059 in) to 5 mm (0.20 in) are preferred. Both males and females use leaf volatiles and sesquiterpenes in the bark to locate hosts. Damage occurs in infested trees by larval feeding. The serpentine feeding galleries of the larvae disrupt the flow of nutrients and water, effectively girdling, thus killing the tree, as it is no longer able to transport sufficient water and nutrients to the leaves to survive. Girdled ashes will often attempt to regenerate through stump sprouting, and there is evidence that stressed trees may also generate higher than normal seed crops as an emergency measure.

Invasiveness

A green ash killed by emerald ash borers
A swamp ash with bark stripped by woodpeckers feeding on emerald ash borers

Outside its native range, emerald ash borer is an invasive species that is highly destructive to ash trees in its introduced range. Before emerald ash borer was found in North America, very little was known about the insect in its native range aside from a short description of life-history traits and taxonomic descriptions, which resulted in focused research on its biology in North America. The insect was first identified in Canton, Michigan (near Detroit), in 2002, but it may have been in the U.S. since the late 1980s. It is suspected that it was introduced from overseas in shipping materials such as packing crates.

Without factors that would normally suppress emerald ash borer populations in its native range (e.g., resistant trees, predators, and parasitoid wasps), populations can quickly rise to damaging levels. After initial infestation, all ash trees are expected to die in an area within 10 years without control measures. Every North American ash species has susceptibility to emerald ash borer, as North American species planted in China also have high mortality from infestations, but some Asian ash species are resistant, including F. baroniana, F. chinensis, F. floribunda, F. mandshurica, and F. platypoda.

Green ash and black ash trees are preferred by emerald ash borer. White ash is also killed rapidly but usually only after all green and black ash trees are eliminated. Blue ash is known to exhibit a higher degree of resistance to emerald ash borer, which is believed to be caused by the high tannin content in the leaves making the foliage unpalatable to the insect. While most Asian ashes have evolved this defense, it is absent from American species other than blue ash. Researchers have examined populations of so-called "lingering ash", trees that survived ash borer attack with little or no damage, as a means of grafting or breeding new, resistant stock. Many of these lingering ashes were found to have unusual phenotypes that may result in increased resistance. Aside from their higher tannin content, Asian ashes also employ natural defenses to repel, trap, and kill emerald ash borer larvae. Although studies of American ashes have suggested that they are capable of mustering similar defensive mechanisms, the trees do not appear to recognize when they are under attack. Many of the specialized predators and parasitoids that suppressed emerald ash borer in Asia were not present in North America. Predators and parasitoids native to North America do not sufficiently suppress emerald ash borer, so populations continue to grow. Birds such as woodpeckers feed on emerald ash borer larva, although the adult beetles have not been used by any American fauna as food. Emerald ash borer populations can spread between 2.5 to 20 km (1.6 to 12.4 mi) per year. It primarily spreads through flight or by transportation of ash bark containing products such as firewood or nursery stock, which allows it to reach new areas and create satellite populations outside of the main infestation.

Other factors can limit spread. Winter temperatures of approximately −38 °C (−36 °F) limit range expansion, and overwintering emerald ash borer survive down to average temperatures of −30 °C (−22 °F) because of antifreeze chemicals in the body and insulation provided by tree bark. Larvae can also survive high heat up to 53 °C (127 °F). Conversely, much like ashes grown in the nursery trade, the population of emerald ash borer in North America is believed to have originated from a single group of insects from central China and also exhibits low genetic diversity.

North American predators and parasitoids can occasionally cause high emerald ash borer mortality, but generally offer only limited control. Mortality from native woodpeckers is variable. Parasitism by parasitoids such as Atanycolus cappaerti can be high, but overall such control is generally low.

The United States Department of Agriculture's Animal and Plant Health Inspection Service published a rule on December 14, 2020—to take effect one month later, January 14, 2021—ending all EAB quarantine activities in the United States due to ineffectiveness so far. Other means will be used instead, especially biological controls (see §Biological control below).

These insects have managed to eliminate close to 300,000 Ash trees in the National Capital Region in only nine years. This leaves only 80,000 ash trees left standing either due to luck or to some amount of resistance to the beetles. These forests used to have an extremely dense Ash population having 17-18 trees per Hectare now there are only 5-6 trees per Hectare. This illustrates extremely well the overall destructive power of the Emerald Ash Borer and the relevance to the everyday person. Something extremely important to note about this severe loss of Ash trees is the effect that it has on the ecosystem of that area. Swamplands that used to be home many Ash forest have now become shrublands, completely changing the ecosystem of that area permanently. The impact this has on the wildlife is extreme because of all the animals that used every part of the tree as refuge, such as birds in the foliage, small rodents amongst the roots, etc.

Environmental and economic impacts

Emerald ash borer threatens the entire North American genus Fraxinus. It has killed tens of millions of ash trees so far and threatens to kill most of the 8.7 billion ash trees throughout North America. Emerald ash borer kills young trees several years before reaching their seeding age of 10 years. In both North America and Europe, the loss of ash from an ecosystem can result in increased numbers of invasive plants, changes in soil nutrients, and effects on species that feed on ash.

Damage and efforts to control the spread of emerald ash borer have affected businesses that sell ash trees or wood products, property owners, and local or state governments. Quarantines can limit the transport of ash trees and products, but economic impacts are especially high for urban and residential areas because of treatment or removal costs and decreased land value from dying trees. Costs for managing these trees can fall upon homeowners or local municipalities. For municipalities, removing large numbers of dead or infested trees at once is costly, so slowing down the rate at which trees die through removing known infested trees and treating trees with insecticides can allow local governments more time to plan, remove, and replace trees that would eventually die. This strategy saves money as it would cost $10.7 billion in urban areas of 25 states over 10 years, while removing and replacing all ash trees in these same areas at once would cost $25 billion (with another estimate putting the removal alone at $20–60 billion). Some urban areas such as Minneapolis have large amounts of ash with slightly more than 20% of their urban forest as ash.

Monitoring

In areas where emerald ash borer has not yet been detected, surveys are used to monitor for new infestations. Visual surveys are used to find ash trees displaying emerald ash borer damage, and traps with colors attractive to emerald ash borer, such as purple or green, are hung in trees as part of a monitoring program. These traps can also have volatile pheromones applied to them that attract primarily males.

A purple trap used for determining the extent of the invasion

Sometimes trees are girdled to act as trap trees to monitor for emerald ash borer. The stressed tree attracts egg-laying females in the spring, and trees can be debarked in the fall to search for larvae. If detected, an area is often placed under a quarantine to prevent infested wood material from causing new infestations. Further control measures are then taken within the area to slow population growth by reducing beetle numbers, preventing them from reaching reproductive maturity and dispersing, and reducing the abundance of ash trees.

Government agencies in both the U.S. and Canada have utilized a native species of parasitoid wasp, Cerceris fumipennis, as a means of detecting areas to which emerald ash borer has spread. The females of these wasps hunt other jewel beetles and emerald ash borer if it is present. The wasps stun the beetles and carry them back to their burrows in the ground where they are stored until the wasps’ eggs hatch and the wasp larvae feed on the beetles. Volunteers catch the wasps as they return to their burrows carrying the beetles to determine whether emerald ash borer is present. This methodology is known as biological surveillance, as opposed to biological control, because it does not appear that the wasps have a significant negative impact on emerald ash borer populations.

Management

In areas where emerald ash borer is non-native and invasive, quarantines, infested tree removal, insecticides, and biological control are used to reduce damage to ash trees.

Quarantine and tree removal

Once an infestation is detected, quarantines are typically imposed by state, or previously, national government agencies disallowing transport of ash firewood or live plants outside of these areas without permits indicating the material has been inspected or treated (i.e., heat treatment or wood chipping) to ensure no live emerald ash borer are present in the bark and phloem. In urban areas, trees are often removed once an infestation is found to reduce emerald ash borer population densities and the likelihood of further spread. Urban ash are typically replaced with non-ash species such as maple, oak, or linden to limit food sources. In rural areas, trees can be harvested for lumber or firewood to reduce ash stand density, but quarantines may apply for this material, especially in areas where the material could be infested.

Kentucky Extension specialists suggest selecting uncommon species to replace removed ashes in the landscape. Previous generations created monocultures by planting ash trees in an overabundance, a factor in the extent of the devastation caused by the emerald ash borer. Favoring instead a diversity in species helps keep urban forests healthy. University of Kentucky scientists suggest choosing monotypic species such as the pawpaw, yellowwood, Franklin tree, Kentucky coffeetree, Osage orange, sourwood, and bald cypress.

Insecticides

Treatment of an ash tree on a street in Montreal with the biopesticide TreeAzin

Insecticides with active ingredients such as azadirachtin, imidacloprid, emamectin benzoate, and dinotefuran are currently used. Dinotefuran and imidacloprid are systemic (i.e., incorporated into the tree) and remain effective for one to three years depending on the product. Insecticides are typically only considered a viable option in urban areas with high value trees near an infestation. Ash trees are primarily treated by direct injection into the tree or soil drench. Some insecticides cannot be applied by homeowners and must be applied by licensed applicators. Damage from emerald ash borer can continue to increase over time even with insecticide applications. Insecticide treatments are not feasible for large forested areas outside of urban areas.

Biological control

Tetrastichus planipennisi, a parasitoid wasp used as a biological control agent

The native range of emerald ash borer in Asia was surveyed for parasitoid species that parasitize emerald ash borer and do not attack other insect species in the hope they would suppress populations when released in North America. Three species imported from China were approved for release by the USDA in 2007 and in Canada in 2013: Spathius agrili, Tetrastichus planipennisi, and Oobius agrili, while Spathius galinae was approved for release in 2015. Excluding Spathius galinae, which has only recently been released, the other three species have been documented parasitizing emerald ash borer larvae one year after release, indicating that they survived the winter, but establishment varied among species and locations. Tetrastichus planipennisi and Oobius agrili established and have had increasing populations in Michigan since 2008; Spathius agrili has had lower establishment success in North America, which could be caused by a lack of available emerald ash borer larvae at the time of adult emergence in spring, limited cold tolerance, and better suitability to regions of North America below the 40th parallel.

The USDA is also assessing the application of Beauveria bassiana, an insect fungal pathogen, for controlling emerald ash borer in conjunction with parasitoid wasps.

See also

References

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External links

Taxon identifiers
Agrilus planipennis
Categories: