Snail populations, beech litter production, and the role of snails in litter decomposition
Identifieur interne : 007548 ( Istex/Corpus ); précédent : 007547; suivant : 007549Snail populations, beech litter production, and the role of snails in litter decomposition
Auteurs : C. F. MasonSource :
- Oecologia [ 0029-8549 ] ; 1970-09-01.
English descriptors
- KwdEn :
- Acanthinula, Acanthinula aculeata, Aculeata, Aggregation, Annual ingestion, Annual litter fall, Annual litter input, Annual production, April, Autumn population, Beech, Beech litter, Beech litter fall, Beech litter production, Beech material, Best approximation, Biomass, Biomass determination, Body weight, Carychium, Carychium tridentatum, Carychlum tridentatum, Cepaea nemoralis, Certain times, Confidence limits, Constant weight, Contracta, Dead animals, Decomposition processes, Discus, Dominant species, Ecol, Ecology, European beech, Extraction efficiency, Field layer, Flotation method, Forest soil, Fraxinus excelsior, Fruit fall, Fruit production, Helicella virgata, High production, Higher population density, Holland publ, Hygromia, Hygromia striolata, Important species, Individual species, Ingestion, Ingestion rate, June, Land molluscs, Land snail, Large numbers, Large species, Leaf litter, Litter, Litter decomposition, Litter fall, Litter production, Litter turnover time, Metabolic activity, Mfiller, Mollusc, Monthly input, Numerous species, Oribatid mites, Other sites, Other species, Oxychilus cellarius, Percentage assimilation, Plant material, Polythene bowl, Population densities, Population density, Population estimates, Present study, Primary production, Punctum pygmaeum, Puncture, Puncture pygmaeum, Pura, Pygmaeum, Retinella, Retinella pura, Sampling occasions, Sampling period, Sampling programme, Sampling techniques, September, Single species, Small animals, Snail, Snail population, Snarl, Soil organisms, Sparse field layer, Species concept, Striolata, Strong light, Subsidiary sites, Total litter fall, Total litter input, Total litter loss, Total litter production, Total population, Tridentatum, Twig, Vitrea, Vitrea contracta, Water surface, Woodland, Woodland floor, Woodland snails, Wytham woods, Zool.
- Teeft :
- Acanthinula, Acanthinula aculeata, Aculeata, Aggregation, Annual ingestion, Annual litter fall, Annual litter input, Annual production, April, Autumn population, Beech, Beech litter, Beech litter fall, Beech litter production, Beech material, Best approximation, Biomass, Biomass determination, Body weight, Carychium, Carychium tridentatum, Carychlum tridentatum, Cepaea nemoralis, Certain times, Confidence limits, Constant weight, Contracta, Dead animals, Decomposition processes, Discus, Dominant species, Ecol, Ecology, European beech, Extraction efficiency, Field layer, Flotation method, Forest soil, Fraxinus excelsior, Fruit fall, Fruit production, Helicella virgata, High production, Higher population density, Holland publ, Hygromia, Hygromia striolata, Important species, Individual species, Ingestion, Ingestion rate, June, Land molluscs, Land snail, Large numbers, Large species, Leaf litter, Litter, Litter decomposition, Litter fall, Litter production, Litter turnover time, Metabolic activity, Mfiller, Mollusc, Monthly input, Numerous species, Oribatid mites, Other sites, Other species, Oxychilus cellarius, Percentage assimilation, Plant material, Polythene bowl, Population densities, Population density, Population estimates, Present study, Primary production, Punctum pygmaeum, Puncture, Puncture pygmaeum, Pura, Pygmaeum, Retinella, Retinella pura, Sampling occasions, Sampling period, Sampling programme, Sampling techniques, September, Single species, Small animals, Snail, Snail population, Snarl, Soil organisms, Sparse field layer, Species concept, Striolata, Strong light, Subsidiary sites, Total litter fall, Total litter input, Total litter loss, Total litter production, Total population, Tridentatum, Twig, Vitrea, Vitrea contracta, Water surface, Woodland, Woodland floor, Woodland snails, Wytham woods, Zool.
Abstract
Summary: The population densities of snails living in beech litter were studied form March 1968 to April 1969. Litter production over one year was measured and the role of snails in litter disappearance assessed. Snails were extracted from litter using a modified Vágvölgyi (1952) flotation method, extraction efficiencies being 84%. The mean annual population density of the twenty-one species of snail recorded on the main sampling site was estimated at 489/m2. Carychium tridentatum was the most numerous species, with a mean density of 200/m2. Acanthinula aculeata, Punctum pygmaeum and Vitrea contracta also had fairly high mean densities. The mean annual biomass was 699 mg dry wt./m2 or 278 mg ash-free dry wt./m2. Hygromia striolata and Oxychilus cellarius/alliarius were the most important species in terms of biomass on the main site. Within the limits of accuracy imposed by the sampling regime the population densities of four out of five of the species (C. tridentatum, A. aculeata, V. contracta, Retinella pura) studied remained unchanged throughout the year, whereas P. pygmaeum had a significantly higher autumn population. C. tridentatum populations were highly aggregated at all times of the year, most markedly so in June. Other species were aggregated at certain times of the year only. Samples taken from other sites showed total population densities of snails ranging from 185–1082 snails/m2. A total tree litter production of 652 g/m2/annum was recorded of which 584g/m2/annum was of beech material. 72% fell in the October–December period. 58% of the beech litter-fall was leaves, 5.2% bud-scales, 27% fruits and 10% twigs and bark. Summation of appropriate field layer peak standing crops amounted to 23.3 g/m2. This was considered as potential litter and was equivalent to 3.4% of the total litter input. The litter standing on the woodland floor in Septermber 1968 was 2,700 g/m2, hence, assuming a steady state, litter turnover time was estimated as 4.5 years. It was calculated that the total snail population ingested 0.35–0.43% of the annual litter input, of which 49% was assimilated. The role of the individual species is examined in relation to concepts of “key species” in ecosystem functioning. The possible role of slugs in decomposition processes is also discussed.
Url:
DOI: 10.1007/BF00344885
Links to Exploration step
ISTEX:ECD42660B7403ACB5EE361E73864C492BC44BD3ALe document en format XML
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Mason</name><affiliation><mods:affiliation>Animal Ecology Research Group, Department of Zoology, Botanic Garden, High Street, Oxford, England</mods:affiliation></affiliation></author></analytic><monogr></monogr><series><title level="j">Oecologia</title><title level="j" type="abbrev">Oecologia</title><idno type="ISSN">0029-8549</idno><idno type="eISSN">1432-1939</idno><imprint><publisher>Springer-Verlag</publisher><pubPlace>Berlin/Heidelberg</pubPlace><date type="published" when="1970-09-01">1970-09-01</date><biblScope unit="volume">5</biblScope><biblScope unit="issue">3</biblScope><biblScope unit="page" from="215">215</biblScope><biblScope unit="page" to="239">239</biblScope></imprint><idno type="ISSN">0029-8549</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0029-8549</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Acanthinula</term><term>Acanthinula aculeata</term><term>Aculeata</term><term>Aggregation</term><term>Annual ingestion</term><term>Annual litter fall</term><term>Annual litter input</term><term>Annual production</term><term>April</term><term>Autumn population</term><term>Beech</term><term>Beech litter</term><term>Beech litter fall</term><term>Beech litter production</term><term>Beech material</term><term>Best approximation</term><term>Biomass</term><term>Biomass determination</term><term>Body weight</term><term>Carychium</term><term>Carychium tridentatum</term><term>Carychlum tridentatum</term><term>Cepaea nemoralis</term><term>Certain times</term><term>Confidence limits</term><term>Constant weight</term><term>Contracta</term><term>Dead animals</term><term>Decomposition processes</term><term>Discus</term><term>Dominant species</term><term>Ecol</term><term>Ecology</term><term>European beech</term><term>Extraction efficiency</term><term>Field layer</term><term>Flotation method</term><term>Forest soil</term><term>Fraxinus excelsior</term><term>Fruit fall</term><term>Fruit production</term><term>Helicella virgata</term><term>High production</term><term>Higher population density</term><term>Holland publ</term><term>Hygromia</term><term>Hygromia striolata</term><term>Important species</term><term>Individual species</term><term>Ingestion</term><term>Ingestion rate</term><term>June</term><term>Land molluscs</term><term>Land snail</term><term>Large numbers</term><term>Large species</term><term>Leaf litter</term><term>Litter</term><term>Litter decomposition</term><term>Litter fall</term><term>Litter production</term><term>Litter turnover time</term><term>Metabolic activity</term><term>Mfiller</term><term>Mollusc</term><term>Monthly input</term><term>Numerous species</term><term>Oribatid mites</term><term>Other sites</term><term>Other species</term><term>Oxychilus cellarius</term><term>Percentage assimilation</term><term>Plant material</term><term>Polythene bowl</term><term>Population densities</term><term>Population density</term><term>Population estimates</term><term>Present study</term><term>Primary production</term><term>Punctum pygmaeum</term><term>Puncture</term><term>Puncture pygmaeum</term><term>Pura</term><term>Pygmaeum</term><term>Retinella</term><term>Retinella pura</term><term>Sampling occasions</term><term>Sampling period</term><term>Sampling programme</term><term>Sampling techniques</term><term>September</term><term>Single species</term><term>Small animals</term><term>Snail</term><term>Snail population</term><term>Snarl</term><term>Soil organisms</term><term>Sparse field layer</term><term>Species concept</term><term>Striolata</term><term>Strong light</term><term>Subsidiary sites</term><term>Total litter fall</term><term>Total litter input</term><term>Total litter loss</term><term>Total litter production</term><term>Total population</term><term>Tridentatum</term><term>Twig</term><term>Vitrea</term><term>Vitrea contracta</term><term>Water surface</term><term>Woodland</term><term>Woodland floor</term><term>Woodland snails</term><term>Wytham woods</term><term>Zool</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Acanthinula</term><term>Acanthinula aculeata</term><term>Aculeata</term><term>Aggregation</term><term>Annual ingestion</term><term>Annual litter fall</term><term>Annual litter input</term><term>Annual production</term><term>April</term><term>Autumn population</term><term>Beech</term><term>Beech litter</term><term>Beech litter fall</term><term>Beech litter production</term><term>Beech material</term><term>Best approximation</term><term>Biomass</term><term>Biomass determination</term><term>Body weight</term><term>Carychium</term><term>Carychium tridentatum</term><term>Carychlum tridentatum</term><term>Cepaea nemoralis</term><term>Certain times</term><term>Confidence limits</term><term>Constant weight</term><term>Contracta</term><term>Dead animals</term><term>Decomposition processes</term><term>Discus</term><term>Dominant species</term><term>Ecol</term><term>Ecology</term><term>European beech</term><term>Extraction efficiency</term><term>Field layer</term><term>Flotation method</term><term>Forest soil</term><term>Fraxinus excelsior</term><term>Fruit fall</term><term>Fruit production</term><term>Helicella virgata</term><term>High production</term><term>Higher population density</term><term>Holland publ</term><term>Hygromia</term><term>Hygromia striolata</term><term>Important species</term><term>Individual species</term><term>Ingestion</term><term>Ingestion rate</term><term>June</term><term>Land molluscs</term><term>Land snail</term><term>Large numbers</term><term>Large species</term><term>Leaf litter</term><term>Litter</term><term>Litter decomposition</term><term>Litter fall</term><term>Litter production</term><term>Litter turnover time</term><term>Metabolic activity</term><term>Mfiller</term><term>Mollusc</term><term>Monthly input</term><term>Numerous species</term><term>Oribatid mites</term><term>Other sites</term><term>Other species</term><term>Oxychilus cellarius</term><term>Percentage assimilation</term><term>Plant material</term><term>Polythene bowl</term><term>Population densities</term><term>Population density</term><term>Population estimates</term><term>Present study</term><term>Primary production</term><term>Punctum pygmaeum</term><term>Puncture</term><term>Puncture pygmaeum</term><term>Pura</term><term>Pygmaeum</term><term>Retinella</term><term>Retinella pura</term><term>Sampling occasions</term><term>Sampling period</term><term>Sampling programme</term><term>Sampling techniques</term><term>September</term><term>Single species</term><term>Small animals</term><term>Snail</term><term>Snail population</term><term>Snarl</term><term>Soil organisms</term><term>Sparse field layer</term><term>Species concept</term><term>Striolata</term><term>Strong light</term><term>Subsidiary sites</term><term>Total litter fall</term><term>Total litter input</term><term>Total litter loss</term><term>Total litter production</term><term>Total population</term><term>Tridentatum</term><term>Twig</term><term>Vitrea</term><term>Vitrea contracta</term><term>Water surface</term><term>Woodland</term><term>Woodland floor</term><term>Woodland snails</term><term>Wytham woods</term><term>Zool</term></keywords></textClass><langUsage><language ident="en">en</language></langUsage></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">Summary: The population densities of snails living in beech litter were studied form March 1968 to April 1969. Litter production over one year was measured and the role of snails in litter disappearance assessed. Snails were extracted from litter using a modified Vágvölgyi (1952) flotation method, extraction efficiencies being 84%. The mean annual population density of the twenty-one species of snail recorded on the main sampling site was estimated at 489/m2. Carychium tridentatum was the most numerous species, with a mean density of 200/m2. Acanthinula aculeata, Punctum pygmaeum and Vitrea contracta also had fairly high mean densities. The mean annual biomass was 699 mg dry wt./m2 or 278 mg ash-free dry wt./m2. Hygromia striolata and Oxychilus cellarius/alliarius were the most important species in terms of biomass on the main site. Within the limits of accuracy imposed by the sampling regime the population densities of four out of five of the species (C. tridentatum, A. aculeata, V. contracta, Retinella pura) studied remained unchanged throughout the year, whereas P. pygmaeum had a significantly higher autumn population. C. tridentatum populations were highly aggregated at all times of the year, most markedly so in June. Other species were aggregated at certain times of the year only. Samples taken from other sites showed total population densities of snails ranging from 185–1082 snails/m2. A total tree litter production of 652 g/m2/annum was recorded of which 584g/m2/annum was of beech material. 72% fell in the October–December period. 58% of the beech litter-fall was leaves, 5.2% bud-scales, 27% fruits and 10% twigs and bark. Summation of appropriate field layer peak standing crops amounted to 23.3 g/m2. This was considered as potential litter and was equivalent to 3.4% of the total litter input. The litter standing on the woodland floor in Septermber 1968 was 2,700 g/m2, hence, assuming a steady state, litter turnover time was estimated as 4.5 years. It was calculated that the total snail population ingested 0.35–0.43% of the annual litter input, of which 49% was assimilated. The role of the individual species is examined in relation to concepts of “key species” in ecosystem functioning. The possible role of slugs in decomposition processes is also discussed.</div></front></TEI><istex><corpusName>springer</corpusName><keywords><teeft><json:string>biomass</json:string><json:string>tridentatum</json:string><json:string>litter</json:string><json:string>carychium</json:string><json:string>retinella</json:string><json:string>snail</json:string><json:string>present study</json:string><json:string>aculeata</json:string><json:string>twig</json:string><json:string>contracta</json:string><json:string>june</json:string><json:string>acanthinula</json:string><json:string>pygmaeum</json:string><json:string>vitrea</json:string><json:string>pura</json:string><json:string>hygromia</json:string><json:string>ecology</json:string><json:string>carychium tridentatum</json:string><json:string>population densities</json:string><json:string>mollusc</json:string><json:string>september</json:string><json:string>ecol</json:string><json:string>total litter fall</json:string><json:string>striolata</json:string><json:string>mfiller</json:string><json:string>discus</json:string><json:string>april</json:string><json:string>ingestion</json:string><json:string>puncture</json:string><json:string>snarl</json:string><json:string>acanthinula aculeata</json:string><json:string>beech litter</json:string><json:string>vitrea contracta</json:string><json:string>zool</json:string><json:string>annual ingestion</json:string><json:string>litter production</json:string><json:string>field layer</json:string><json:string>retinella pura</json:string><json:string>sampling occasions</json:string><json:string>population density</json:string><json:string>holland publ</json:string><json:string>soil organisms</json:string><json:string>annual litter input</json:string><json:string>puncture pygmaeum</json:string><json:string>aggregation</json:string><json:string>woodland</json:string><json:string>wytham woods</json:string><json:string>beech</json:string><json:string>sparse field layer</json:string><json:string>numerous species</json:string><json:string>woodland floor</json:string><json:string>primary production</json:string><json:string>litter decomposition</json:string><json:string>other species</json:string><json:string>constant weight</json:string><json:string>extraction efficiency</json:string><json:string>dead animals</json:string><json:string>metabolic activity</json:string><json:string>large species</json:string><json:string>beech litter production</json:string><json:string>snail population</json:string><json:string>water surface</json:string><json:string>best approximation</json:string><json:string>cepaea nemoralis</json:string><json:string>biomass determination</json:string><json:string>plant material</json:string><json:string>strong light</json:string><json:string>oxychilus cellarius</json:string><json:string>single species</json:string><json:string>population estimates</json:string><json:string>polythene bowl</json:string><json:string>sampling programme</json:string><json:string>carychlum tridentatum</json:string><json:string>sampling period</json:string><json:string>large numbers</json:string><json:string>autumn population</json:string><json:string>subsidiary sites</json:string><json:string>higher population density</json:string><json:string>monthly input</json:string><json:string>annual production</json:string><json:string>fraxinus excelsior</json:string><json:string>total litter production</json:string><json:string>woodland snails</json:string><json:string>decomposition processes</json:string><json:string>body weight</json:string><json:string>individual species</json:string><json:string>percentage assimilation</json:string><json:string>sampling techniques</json:string><json:string>litter turnover time</json:string><json:string>small animals</json:string><json:string>confidence limits</json:string><json:string>total litter input</json:string><json:string>dominant species</json:string><json:string>helicella virgata</json:string><json:string>total population</json:string><json:string>beech material</json:string><json:string>litter fall</json:string><json:string>beech litter fall</json:string><json:string>fruit fall</json:string><json:string>total litter loss</json:string><json:string>high production</json:string><json:string>fruit production</json:string><json:string>annual litter fall</json:string><json:string>leaf litter</json:string><json:string>ingestion rate</json:string><json:string>species concept</json:string><json:string>other sites</json:string><json:string>oribatid mites</json:string><json:string>certain times</json:string><json:string>important species</json:string><json:string>hygromia striolata</json:string><json:string>forest soil</json:string><json:string>punctum pygmaeum</json:string><json:string>land snail</json:string><json:string>flotation method</json:string><json:string>european beech</json:string><json:string>land molluscs</json:string></teeft></keywords><author><json:item><name>C. F. Mason</name><affiliations><json:string>Animal Ecology Research Group, Department of Zoology, Botanic Garden, High Street, Oxford, England</json:string></affiliations></json:item></author><articleId><json:string>BF00344885</json:string><json:string>Art4</json:string></articleId><arkIstex>ark:/67375/1BB-1ZMP2CJH-8</arkIstex><language><json:string>eng</json:string></language><originalGenre><json:string>OriginalPaper</json:string></originalGenre><abstract>Summary: The population densities of snails living in beech litter were studied form March 1968 to April 1969. Litter production over one year was measured and the role of snails in litter disappearance assessed. Snails were extracted from litter using a modified Vágvölgyi (1952) flotation method, extraction efficiencies being 84%. The mean annual population density of the twenty-one species of snail recorded on the main sampling site was estimated at 489/m2. Carychium tridentatum was the most numerous species, with a mean density of 200/m2. Acanthinula aculeata, Punctum pygmaeum and Vitrea contracta also had fairly high mean densities. The mean annual biomass was 699 mg dry wt./m2 or 278 mg ash-free dry wt./m2. Hygromia striolata and Oxychilus cellarius/alliarius were the most important species in terms of biomass on the main site. Within the limits of accuracy imposed by the sampling regime the population densities of four out of five of the species (C. tridentatum, A. aculeata, V. contracta, Retinella pura) studied remained unchanged throughout the year, whereas P. pygmaeum had a significantly higher autumn population. C. tridentatum populations were highly aggregated at all times of the year, most markedly so in June. Other species were aggregated at certain times of the year only. Samples taken from other sites showed total population densities of snails ranging from 185–1082 snails/m2. A total tree litter production of 652 g/m2/annum was recorded of which 584g/m2/annum was of beech material. 72% fell in the October–December period. 58% of the beech litter-fall was leaves, 5.2% bud-scales, 27% fruits and 10% twigs and bark. Summation of appropriate field layer peak standing crops amounted to 23.3 g/m2. This was considered as potential litter and was equivalent to 3.4% of the total litter input. The litter standing on the woodland floor in Septermber 1968 was 2,700 g/m2, hence, assuming a steady state, litter turnover time was estimated as 4.5 years. It was calculated that the total snail population ingested 0.35–0.43% of the annual litter input, of which 49% was assimilated. The role of the individual species is examined in relation to concepts of “key species” in ecosystem functioning. The possible role of slugs in decomposition processes is also discussed.</abstract><qualityIndicators><score>10</score><pdfWordCount>7917</pdfWordCount><pdfCharCount>47093</pdfCharCount><pdfVersion>1.3</pdfVersion><pdfPageCount>25</pdfPageCount><pdfPageSize>446.28 x 662.28 pts</pdfPageSize><refBibsNative>false</refBibsNative><abstractWordCount>359</abstractWordCount><abstractCharCount>2303</abstractCharCount><keywordCount>0</keywordCount></qualityIndicators><title>Snail populations, beech litter production, and the role of snails in litter decomposition</title><pmid><json:string>28309821</json:string></pmid><genre><json:string>research-article</json:string></genre><host><title>Oecologia</title><language><json:string>unknown</json:string></language><publicationDate>1970</publicationDate><copyrightDate>1970</copyrightDate><issn><json:string>0029-8549</json:string></issn><eissn><json:string>1432-1939</json:string></eissn><journalId><json:string>442</json:string></journalId><volume>5</volume><issue>3</issue><pages><first>215</first><last>239</last></pages><genre><json:string>journal</json:string></genre><subject><json:item><value>Ecology</value></json:item><json:item><value>Plant Sciences</value></json:item></subject></host><namedEntities><unitex><date><json:string>1968</json:string><json:string>from March 1968 to April 1969</json:string><json:string>1969</json:string><json:string>period March 1968 to February 1969</json:string><json:string>period 1st July to 30th September</json:string><json:string>1970-03-03</json:string><json:string>from 19th September to 28th November</json:string></date><geogName><json:string>Wytham</json:string></geogName><orgName><json:string>Natural Environment Research Council Studentship</json:string></orgName><orgName_funder></orgName_funder><orgName_provider></orgName_provider><persName><json:string>J. Phillipson</json:string><json:string>L. Site</json:string><json:string>C. Pfeiffer</json:string><json:string>June Month</json:string><json:string>F. Mason</json:string><json:string>Norway</json:string><json:string>Lawton</json:string></persName><placeName><json:string>Berkshire</json:string><json:string>Australia</json:string><json:string>Poland</json:string><json:string>Europe</json:string><json:string>Japan</json:string><json:string>Denmark</json:string><json:string>England</json:string><json:string>Netherlands</json:string></placeName><ref_url></ref_url><ref_bibl><json:string>Donov (1964)</json:string><json:string>Megalinski and Orlov (1965)</json:string><json:string>Ovington and Murray (1964)</json:string><json:string>Zangiyev (1960)</json:string><json:string>September 1968</json:string><json:string>Hunter, 1966</json:string><json:string>June was the principle month of egg-laying in a population studied by Morton, 1954</json:string><json:string>Maefadyen, 1961, 1963</json:string><json:string>Boeock, 1963</json:string><json:string>Xira and Shidei (1967)</json:string><json:string>Morton, 1954</json:string><json:string>Lloyd (1963)</json:string><json:string>Grieg-Smith, 1964</json:string><json:string>Valovirta, 1968</json:string><json:string>Pomeroy, 1969</json:string><json:string>April and July 1969</json:string><json:string>Baker, 1968</json:string><json:string>Drift and Witkamp (1958)</json:string><json:string>Edwards and Heath (1963)</json:string><json:string>South, 1965</json:string><json:string>Gere, 1963</json:string><json:string>W~reborn, 1969</json:string><json:string>Debauche, 1962</json:string><json:string>Pomeroy (1969)</json:string><json:string>Bonnevie-Svendsen and Gjems (1957)</json:string><json:string>Bray and Gotham (1964)</json:string><json:string>from Mason, 1970</json:string><json:string>Berthet, 1963</json:string><json:string>Mason (1970)</json:string><json:string>Birch and Clark, 1953</json:string><json:string>Mason, 1970</json:string><json:string>Myczkowski (1967)</json:string><json:string>David and Moore (1954)</json:string><json:string>May and June 1969</json:string><json:string>BonnevieSvendsen and Gjems (1957)</json:string><json:string>AgSesy, 1968</json:string><json:string>Berthet, 1967</json:string></ref_bibl><bibl></bibl></unitex></namedEntities><ark><json:string>ark:/67375/1BB-1ZMP2CJH-8</json:string></ark><categories><wos><json:string>1 - science</json:string><json:string>2 - ecology</json:string></wos><scienceMetrix><json:string>1 - natural sciences</json:string><json:string>2 - biology</json:string><json:string>3 - ecology</json:string></scienceMetrix><scopus><json:string>1 - Life Sciences</json:string><json:string>2 - Agricultural and Biological Sciences</json:string><json:string>3 - Ecology, Evolution, Behavior and Systematics</json:string></scopus><inist><json:string>1 - sciences appliquees, technologies et medecines</json:string><json:string>2 - sciences biologiques et medicales</json:string><json:string>3 - sciences biologiques fondamentales et appliquees. psychologie</json:string></inist></categories><publicationDate>1970</publicationDate><copyrightDate>1970</copyrightDate><doi><json:string>10.1007/BF00344885</json:string></doi><id>ECD42660B7403ACB5EE361E73864C492BC44BD3A</id><score>1</score><fulltext><json:item><extension>pdf</extension><original>true</original><mimetype>application/pdf</mimetype><uri>https://api.istex.fr/document/ECD42660B7403ACB5EE361E73864C492BC44BD3A/fulltext/pdf</uri></json:item><json:item><extension>zip</extension><original>false</original><mimetype>application/zip</mimetype><uri>https://api.istex.fr/document/ECD42660B7403ACB5EE361E73864C492BC44BD3A/fulltext/zip</uri></json:item><istex:fulltextTEI uri="https://api.istex.fr/document/ECD42660B7403ACB5EE361E73864C492BC44BD3A/fulltext/tei"><teiHeader><fileDesc><titleStmt><title level="a" type="main" xml:lang="en">Snail populations, beech litter production, and the role of snails in litter decomposition</title><respStmt><resp>Références bibliographiques récupérées via GROBID</resp><name resp="ISTEX-API">ISTEX-API (INIST-CNRS)</name></respStmt></titleStmt><publicationStmt><authority>ISTEX</authority><publisher scheme="https://publisher-list.data.istex.fr">Springer-Verlag</publisher><pubPlace>Berlin/Heidelberg</pubPlace><availability><licence><p>Springer-Verlag, 1970</p></licence><p scheme="https://loaded-corpus.data.istex.fr/ark:/67375/XBH-3XSW68JL-F">springer</p></availability><date>1970-03-03</date></publicationStmt><notesStmt><note type="research-article" scheme="https://content-type.data.istex.fr/ark:/67375/XTP-1JC4F85T-7">research-article</note><note type="journal" scheme="https://publication-type.data.istex.fr/ark:/67375/JMC-0GLKJH51-B">journal</note></notesStmt><sourceDesc><biblStruct type="inbook"><analytic><title level="a" type="main" xml:lang="en">Snail populations, beech litter production, and the role of snails in litter decomposition</title><author xml:id="author-0000"><persName><forename type="first">C.</forename><surname>Mason</surname></persName><affiliation>Animal Ecology Research Group, Department of Zoology, Botanic Garden, High Street, Oxford, England</affiliation></author><idno type="istex">ECD42660B7403ACB5EE361E73864C492BC44BD3A</idno><idno type="ark">ark:/67375/1BB-1ZMP2CJH-8</idno><idno type="DOI">10.1007/BF00344885</idno><idno type="article-id">BF00344885</idno><idno type="article-id">Art4</idno></analytic><monogr><title level="j">Oecologia</title><title level="j" type="abbrev">Oecologia</title><idno type="pISSN">0029-8549</idno><idno type="eISSN">1432-1939</idno><idno type="journal-ID">true</idno><idno type="issue-article-count">5</idno><idno type="volume-issue-count">4</idno><imprint><publisher>Springer-Verlag</publisher><pubPlace>Berlin/Heidelberg</pubPlace><date type="published" when="1970-09-01"></date><biblScope unit="volume">5</biblScope><biblScope unit="issue">3</biblScope><biblScope unit="page" from="215">215</biblScope><biblScope unit="page" to="239">239</biblScope></imprint></monogr></biblStruct></sourceDesc></fileDesc><profileDesc><creation><date>1970-03-03</date></creation><langUsage><language ident="en">en</language></langUsage><abstract xml:lang="en"><p>Summary: The population densities of snails living in beech litter were studied form March 1968 to April 1969. Litter production over one year was measured and the role of snails in litter disappearance assessed. Snails were extracted from litter using a modified Vágvölgyi (1952) flotation method, extraction efficiencies being 84%. The mean annual population density of the twenty-one species of snail recorded on the main sampling site was estimated at 489/m2. Carychium tridentatum was the most numerous species, with a mean density of 200/m2. Acanthinula aculeata, Punctum pygmaeum and Vitrea contracta also had fairly high mean densities. The mean annual biomass was 699 mg dry wt./m2 or 278 mg ash-free dry wt./m2. Hygromia striolata and Oxychilus cellarius/alliarius were the most important species in terms of biomass on the main site. Within the limits of accuracy imposed by the sampling regime the population densities of four out of five of the species (C. tridentatum, A. aculeata, V. contracta, Retinella pura) studied remained unchanged throughout the year, whereas P. pygmaeum had a significantly higher autumn population. C. tridentatum populations were highly aggregated at all times of the year, most markedly so in June. Other species were aggregated at certain times of the year only. Samples taken from other sites showed total population densities of snails ranging from 185–1082 snails/m2. A total tree litter production of 652 g/m2/annum was recorded of which 584g/m2/annum was of beech material. 72% fell in the October–December period. 58% of the beech litter-fall was leaves, 5.2% bud-scales, 27% fruits and 10% twigs and bark. Summation of appropriate field layer peak standing crops amounted to 23.3 g/m2. This was considered as potential litter and was equivalent to 3.4% of the total litter input. The litter standing on the woodland floor in Septermber 1968 was 2,700 g/m2, hence, assuming a steady state, litter turnover time was estimated as 4.5 years. It was calculated that the total snail population ingested 0.35–0.43% of the annual litter input, of which 49% was assimilated. The role of the individual species is examined in relation to concepts of “key species” in ecosystem functioning. The possible role of slugs in decomposition processes is also discussed.</p></abstract><textClass><keywords scheme="Journal Subject"><list><head>Life Sciences</head><item><term>Ecology</term></item><item><term>Plant Sciences</term></item></list></keywords></textClass></profileDesc><revisionDesc><change when="1970-03-03">Created</change><change when="1970-09-01">Published</change><change xml:id="refBibs-istex" who="#ISTEX-API" when="2017-10-2">References added</change></revisionDesc></teiHeader></istex:fulltextTEI><json:item><extension>txt</extension><original>false</original><mimetype>text/plain</mimetype><uri>https://api.istex.fr/document/ECD42660B7403ACB5EE361E73864C492BC44BD3A/fulltext/txt</uri></json:item></fulltext><metadata><istex:metadataXml wicri:clean="Springer, Publisher found" wicri:toSee="no header"><istex:xmlDeclaration>version="1.0" encoding="UTF-8"</istex:xmlDeclaration><istex:docType PUBLIC="-//Springer-Verlag//DTD A++ V2.4//EN" URI="http://devel.springer.de/A++/V2.4/DTD/A++V2.4.dtd" name="istex:docType"></istex:docType><istex:document><Publisher><PublisherInfo><PublisherName>Springer-Verlag</PublisherName><PublisherLocation>Berlin/Heidelberg</PublisherLocation></PublisherInfo><Journal><JournalInfo JournalProductType="ArchiveJournal" NumberingStyle="Unnumbered"><JournalID>442</JournalID><JournalPrintISSN>0029-8549</JournalPrintISSN><JournalElectronicISSN>1432-1939</JournalElectronicISSN><JournalTitle>Oecologia</JournalTitle><JournalAbbreviatedTitle>Oecologia</JournalAbbreviatedTitle><JournalSubjectGroup><JournalSubject Type="Primary">Life Sciences</JournalSubject><JournalSubject Type="Secondary">Ecology</JournalSubject><JournalSubject Type="Secondary">Plant Sciences</JournalSubject></JournalSubjectGroup></JournalInfo><Volume><VolumeInfo VolumeType="Regular" TocLevels="0"><VolumeIDStart>5</VolumeIDStart><VolumeIDEnd>5</VolumeIDEnd><VolumeIssueCount>4</VolumeIssueCount></VolumeInfo><Issue IssueType="Regular"><IssueInfo TocLevels="0"><IssueIDStart>3</IssueIDStart><IssueIDEnd>3</IssueIDEnd><IssueArticleCount>5</IssueArticleCount><IssueHistory><CoverDate><DateString>10. VIII. 1970</DateString><Year>1970</Year><Month>9</Month></CoverDate></IssueHistory><IssueCopyright><CopyrightHolderName>Springer-Verlag</CopyrightHolderName><CopyrightYear>1970</CopyrightYear></IssueCopyright></IssueInfo><Article ID="Art4"><ArticleInfo Language="En" ArticleType="OriginalPaper" NumberingStyle="Unnumbered" TocLevels="0" ContainsESM="No"><ArticleID>BF00344885</ArticleID><ArticleDOI>10.1007/BF00344885</ArticleDOI><ArticleSequenceNumber>4</ArticleSequenceNumber><ArticleTitle Language="En">Snail populations, beech litter production, and the role of snails in litter decomposition</ArticleTitle><ArticleFirstPage>215</ArticleFirstPage><ArticleLastPage>239</ArticleLastPage><ArticleHistory><RegistrationDate><Year>2004</Year><Month>9</Month><Day>2</Day></RegistrationDate><Received><Year>1970</Year><Month>3</Month><Day>3</Day></Received></ArticleHistory><ArticleCopyright><CopyrightHolderName>Springer-Verlag</CopyrightHolderName><CopyrightYear>1970</CopyrightYear></ArticleCopyright><ArticleGrants Type="Regular"><MetadataGrant Grant="OpenAccess"></MetadataGrant><AbstractGrant Grant="OpenAccess"></AbstractGrant><BodyPDFGrant Grant="Restricted"></BodyPDFGrant><BodyHTMLGrant Grant="Restricted"></BodyHTMLGrant><BibliographyGrant Grant="Restricted"></BibliographyGrant><ESMGrant Grant="Restricted"></ESMGrant></ArticleGrants><ArticleContext><JournalID>442</JournalID><VolumeIDStart>5</VolumeIDStart><VolumeIDEnd>5</VolumeIDEnd><IssueIDStart>3</IssueIDStart><IssueIDEnd>3</IssueIDEnd></ArticleContext></ArticleInfo><ArticleHeader><AuthorGroup><Author AffiliationIDS="Aff1"><AuthorName DisplayOrder="Western"><GivenName>C.</GivenName><GivenName>F.</GivenName><FamilyName>Mason</FamilyName></AuthorName></Author><Affiliation ID="Aff1"><OrgDivision>Animal Ecology Research Group, Department of Zoology</OrgDivision><OrgName>Botanic Garden</OrgName><OrgAddress><Street>High Street</Street><City>Oxford</City><Country>England</Country></OrgAddress></Affiliation></AuthorGroup><Abstract ID="Abs1" Language="En"><Heading>Summary</Heading><Para>The population densities of snails living in beech litter were studied form March 1968 to April 1969. Litter production over one year was measured and the role of snails in litter disappearance assessed.</Para><Para>Snails were extracted from litter using a modified Vágvölgyi (1952) flotation method, extraction efficiencies being 84%. The mean annual population density of the twenty-one species of snail recorded on the main sampling site was estimated at 489/m<Superscript>2</Superscript>. <Emphasis Type="Italic">Carychium tridentatum</Emphasis> was the most numerous species, with a mean density of 200/m<Superscript>2</Superscript>. <Emphasis Type="Italic">Acanthinula aculeata, Punctum pygmaeum</Emphasis> and <Emphasis Type="Italic">Vitrea contracta</Emphasis> also had fairly high mean densities. The mean annual biomass was 699 mg dry wt./m<Superscript>2</Superscript> or 278 mg ash-free dry wt./m<Superscript>2</Superscript>. <Emphasis Type="Italic">Hygromia striolata</Emphasis> and <Emphasis Type="Italic">Oxychilus cellarius/alliarius</Emphasis> were the most important species in terms of biomass on the main site. Within the limits of accuracy imposed by the sampling regime the population densities of four out of five of the species (<Emphasis Type="Italic">C. tridentatum, A. aculeata, V. contracta, Retinella pura</Emphasis>) studied remained unchanged throughout the year, whereas <Emphasis Type="Italic">P. pygmaeum</Emphasis> had a significantly higher autumn population. <Emphasis Type="Italic">C. tridentatum</Emphasis> populations were highly aggregated at all times of the year, most markedly so in June. Other species were aggregated at certain times of the year only. Samples taken from other sites showed total population densities of snails ranging from 185–1082 snails/m<Superscript>2</Superscript>.</Para><Para>A total tree litter production of 652 g/m<Superscript>2</Superscript>/annum was recorded of which 584g/m<Superscript>2</Superscript>/annum was of beech material. 72% fell in the October–December period. 58% of the beech litter-fall was leaves, 5.2% bud-scales, 27% fruits and 10% twigs and bark. Summation of appropriate field layer peak standing crops amounted to 23.3 g/m<Superscript>2</Superscript>. This was considered as potential litter and was equivalent to 3.4% of the total litter input. The litter standing on the woodland floor in Septermber 1968 was 2,700 g/m<Superscript>2</Superscript>, hence, assuming a steady state, litter turnover time was estimated as 4.5 years.</Para><Para>It was calculated that the total snail population ingested 0.35–0.43% of the annual litter input, of which 49% was assimilated. The role of the individual species is examined in relation to concepts of “key species” in ecosystem functioning. The possible role of slugs in decomposition processes is also discussed.</Para></Abstract></ArticleHeader><NoBody></NoBody></Article></Issue></Volume></Journal></Publisher></istex:document></istex:metadataXml><mods version="3.6"><titleInfo lang="en"><title>Snail populations, beech litter production, and the role of snails in litter decomposition</title></titleInfo><titleInfo type="alternative" contentType="CDATA" lang="en"><title>Snail populations, beech litter production, and the role of snails in litter decomposition</title></titleInfo><name type="personal"><namePart type="given">C.</namePart><namePart type="given">F.</namePart><namePart type="family">Mason</namePart><affiliation>Animal Ecology Research Group, Department of Zoology, Botanic Garden, High Street, Oxford, England</affiliation><role><roleTerm type="text">author</roleTerm></role></name><typeOfResource>text</typeOfResource><genre type="research-article" displayLabel="OriginalPaper" authority="ISTEX" authorityURI="https://content-type.data.istex.fr" valueURI="https://content-type.data.istex.fr/ark:/67375/XTP-1JC4F85T-7">research-article</genre><originInfo><publisher>Springer-Verlag</publisher><place><placeTerm type="text">Berlin/Heidelberg</placeTerm></place><dateCreated encoding="w3cdtf">1970-03-03</dateCreated><dateIssued encoding="w3cdtf">1970-09-01</dateIssued><dateIssued encoding="w3cdtf">1970</dateIssued><copyrightDate encoding="w3cdtf">1970</copyrightDate></originInfo><language><languageTerm type="code" authority="rfc3066">en</languageTerm><languageTerm type="code" authority="iso639-2b">eng</languageTerm></language><abstract lang="en">Summary: The population densities of snails living in beech litter were studied form March 1968 to April 1969. Litter production over one year was measured and the role of snails in litter disappearance assessed. Snails were extracted from litter using a modified Vágvölgyi (1952) flotation method, extraction efficiencies being 84%. The mean annual population density of the twenty-one species of snail recorded on the main sampling site was estimated at 489/m2. Carychium tridentatum was the most numerous species, with a mean density of 200/m2. Acanthinula aculeata, Punctum pygmaeum and Vitrea contracta also had fairly high mean densities. The mean annual biomass was 699 mg dry wt./m2 or 278 mg ash-free dry wt./m2. Hygromia striolata and Oxychilus cellarius/alliarius were the most important species in terms of biomass on the main site. Within the limits of accuracy imposed by the sampling regime the population densities of four out of five of the species (C. tridentatum, A. aculeata, V. contracta, Retinella pura) studied remained unchanged throughout the year, whereas P. pygmaeum had a significantly higher autumn population. C. tridentatum populations were highly aggregated at all times of the year, most markedly so in June. Other species were aggregated at certain times of the year only. Samples taken from other sites showed total population densities of snails ranging from 185–1082 snails/m2. A total tree litter production of 652 g/m2/annum was recorded of which 584g/m2/annum was of beech material. 72% fell in the October–December period. 58% of the beech litter-fall was leaves, 5.2% bud-scales, 27% fruits and 10% twigs and bark. Summation of appropriate field layer peak standing crops amounted to 23.3 g/m2. This was considered as potential litter and was equivalent to 3.4% of the total litter input. The litter standing on the woodland floor in Septermber 1968 was 2,700 g/m2, hence, assuming a steady state, litter turnover time was estimated as 4.5 years. It was calculated that the total snail population ingested 0.35–0.43% of the annual litter input, of which 49% was assimilated. The role of the individual species is examined in relation to concepts of “key species” in ecosystem functioning. 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