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Ayrışma Sürecinde Orman Karıncalarının (Formica rufa grup) Rolü: İlk Yıl Sonuçları

Year 2019, Volume: 21 Issue: 2, 477 - 485, 15.08.2019

Abstract



Orman
karıncaları (Formica rufa grup)
ılıman kuşaktaki ibreli ormanlarda baskın olarak bulunan karınca grubudur.
Toprak üstündeki büyük yuvalarını orman tabanından topladıkları organik
materyal ve reçine ile inşa ederler. Bu yuvalar yüksek sıcaklık ve düşük nem
içeriği bakımından çevrelerinden farklılık gösterirler.  Bu çalışmada bu özel çevresel şartların,
ölüörtünün kütle kaybı ile karbon (C), azot (N),
potasyum
(K),
fosfor (P), mangan (Mn), demir (Fe) ve alüminyum (Al)’u
ayrışma sürecinde nasıl etkilediğine bakılmıştır. Çalışma Çankırı Karatekin
Üniversitesi Orman Fakültesi Araştırma ve Uygulama Ormanında saf karaçam (
Pinus nigra Arnold.) ormanında, ölüörtü kese yöntemi kullanılarak
yürütülmüştür. Karaçam ibreleri karınca yuvalarının hemen kenarına ve yuvadan
10 m uzağa konulmuştur.

Karıncaların
etkisi ve kurak yuva şartları nedeni ile ayrışmanın yavaş olmasını beklerken,
karınca yuvalarının, karaçam
ibrelerinin ayrışma sürecinde, kütle kaybı, karbon, azot, potasyum ve fosfor’un
zamansal değişimi üzerinde istatistiksel olarak fark yaratacak etkiye sahip
olmadığı belirlenmiştir. Fakat mangan, alüminyum ve demir gibi elementlerin
zamansal değişiminde karınca yuvalarının, orman toprağına kıyasla bu
elementlerin toprağa girişinde yavaşlatıcı
etkiye sahip oldukları
bulunmuştur.




Supporting Institution

TÜBİTAK

Project Number

1919B011402186

Thanks

Bu çalışma, TÜBİTAK 2209 Üniversite Öğrencileri Yurt İçi Araştırma Projeleri Destekleme Programı’nın 1919B011402186 nolu projesi tarafından desteklenmiştir.

References

  • Abay G, Ursavaş S (2009). Çankırı ili araştırma ormanı karayosunu (musci) flora ve ekolojisi. Bartın Orman Fakültesi Dergisi, 11: 61-70.
  • Aerts R (1997). Climate, leaf litter chemistry and leaf litter decomposition in terrestrial ecosystems: a triangular relationship. Oikos, 79: 439-449.
  • Berg B, Erhagen B, Johansson MB, Vesterdal L, Faituri M, Sanborn P, Nilsson M (2013). Manganese dynamics in decomposing needle and leaf litter—a synthesis. Canadian journal of forest research, 43: 1127-1136.
  • Berg B, McClaugherty C (2014). Plant litter, Decomposition, humus formation, carbon sequestration. Third Edition. Springer-Verlag, Berlin Heidelberg.
  • Berg B, Staaf H (1981). Leaching, acccumulation and release of nitrogen in decomposing forest litter. Terresterial Nitrogen Cycles. Ecological Bulletin, 33: 163-178.
  • Berg B, Steffen K, McClaugherty C (2007). Litter decomposition rate is dependent on litter Mn concentrations. Biogeochemistry, 82: 29-39.
  • Berger TW, Duboc O, Djukic I, Tatzber M, Gerzabek MH, Zehetner F (2015). Decomposition of beech (Fagus sylvatica) and pine (Pinus nigra) litter along an Alpine elevation gradient: decay and nutrient release. Geoderma, 251: 92-104.
  • Cammeraat E, Risch A (2008). The impact of ants on mineral soil properties and processes at different spatial scales. Journal of Applied Entomology, 132: 285-294.
  • Coleman DC, Crossley DA, Hendrix PF (2004). Fundamentals of soil ecology. Academic press, USA.
  • Çakır M, Akburak S (2017). Litterfall and nutrients return to soil in pure and mixed stands of oak and beech. Journal of The Faculty of Forestry Istanbul University, 67: 185-200.
  • Davey MP, Berg B, Emmett BA, Rowland P (2007). Decomposition of oak leaf litter is related to initial litter Mn concentrations. Botany, 85: 16-24.
  • Domisch T, Ohashi M, Finér L, Risch A, Sundström L, Kilpeläinen J, Niemelä P (2008). Decomposition of organic matter and nutrient mineralisation in wood ant (Formica rufa group) mounds in boreal coniferous forests of different age. Biology and Fertility of Soils, 44: 539-545.
  • Dutta RK, Agrawal MJP (2001). Litterfall, litter decomposition and nutrient release in five exotic plant species planted on coal mine spoils. 45: 298-312.
  • Frankland JC (1998). Fungal succession—unravelling the unpredictable. Mycological research, 102: 1-15.
  • Frouz J (2000). The effect of nest moisture on daily temperature regime in the nests of Formica polyctena wood ants. Insectes Sociaux, 47: 229-235.
  • Frouz J, Holec M, Kalčík J (2003). The effect of Lasius niger (Hymenoptera, Formicidae) ant nest on selected soil chemical properties. Pedobiologia, 47: 205-212.
  • Frouz J, Jílková V, Sorvari J (2016). Contribution of wood ants to nutrient cycling and ecosystem function. In: Stockan, J.A., Robinson, E.J.H. (Eds.), Wood Ant Ecology and Conservation. Cambridge University Press, U.K., p. 207.
  • Frouz J, Kalčík J, Cudlín P (2005). Accumulation of phosphorus in nests of red wood ants Formica s. str. Annales Zoologici Fennici, 42: 269-275.
  • Goya JF, Frangi JL, Pérez CA, Dalla Tea F (2008). Decomposition and nutrient release from leaf litter in Eucalyptus grandis plantations on three different soils in Entre Ríos, Argentina. Bosque, 29.
  • Göl C, Yılmaz H, Ediş S (2010). Orman fakültesi araştırma ve uygulama ormanı topraklarının bazı özellikleri ve sınıflandırması. In, III. Ulusal Karadeniz Ormancılık Kongresi, Artvin, pp. 941-952.
  • Güner Ş, Çömez A (2017). Biomass equations and changes in carbon stock in afforested black pine (Pinus nigra Arnold. subsp. pallasiana (Lamb.) Holmboe) stands in Turkey. Fresenius Environmental Bulletin, 26: 2368-2379.
  • Hoorens B, Aerts R, Stroetenga M (2003). Does initial litter chemistry explain litter mixture effects on decomposition? Oecologia, 137: 578-586.
  • Jílková V, Cajthaml T, Frouz J (2018). Relative importance of honeydew and resin for the microbial activity in wood ant nest and forest floor substrate–a laboratory study. Soil Biology Biochemistry, 117: 1-4.
  • Jílková V, Matějíček L, Frouz J (2011). Changes in the pH and other soil chemical parameters in soil surrounding wood ant (Formica polyctena) nests. European Journal of Soil Biology, 47: 72-76.
  • Jílková V, Šebek O, Frouz J (2012). Mechanisms of pH change in wood ant (Formica polyctena) nests. Pedobiologia, 55: 247-251.
  • Jurgensen M, Finer L, Domisch T, Kilpeläinen J, Punttila P, Ohashi M, Niemelä P, Sundström L, Neuvonen S, Risch A (2008). Organic mound‐building ants: their impact on soil properties in temperate and boreal forests. Journal of Applied Entomology, 132: 266-275.
  • Kilpeläinen J, Finér L, Niemelä P, Domisch T, Neuvonen S, Ohashi M, Risch A, Sundström L (2007). Carbon, nitrogen and phosphorus dynamics of ant mounds (Formica rufa group) in managed boreal forests of different successional stages. Applied Soil Ecology, 36: 156-163.
  • Kristiansen S, Amelung W (2001). Abandoned anthills of Formica polyctena and soil heterogeneity in a temperate deciduous forest: morphology and organic matter composition. European Journal of Soil Science, 52: 355-363.
  • Laakso J, Setälä H (1997). Nest mounds of red wood ants (Formica aquilonia): hot spots for litter-dwelling earthworms. Oecologia, 111: 565-569.
  • Laakso J, Setälä H (1998). Composition and trophic structure of detrital food web in ant nest mounds of Formica aquilonia and in the surrounding forest soil. Oikos: 266-278.
  • Laakso J, Setälä H (2000). Impacts of wood ants (Formica aquilonia Yarr.) on the invertebrate food web of the boreal forest floor. Annales Zoologici Fennici, 37: 93-100.
  • Lenoir L, Bengtsson J, Persson T (2003). Effects of Formica ants on soil fauna-results from a short-term exclusion and a long-term natural experiment. Oecologia, 134: 423-430.
  • Lenoir L, Persson T, Bengtsson J (2001). Wood ant nests as potential hot spots for carbon and nitrogen mineralisation. Biology and fertility of Soils, 34: 235-240.
  • Manzoni S, Trofymow JA, Jackson RB, Porporato A (2010). Stoichiometric controls on carbon, nitrogen, and phosphorus dynamics in decomposing litter. Ecological Monographs, 80: 89-106.
  • Nkem JN, Lobry de Bruyn LA, Grant CD, Hulugalle NR (2000). The impact of ant bioturbation and foraging activities on surrounding soil properties. Pedobiologia, 44: 609-621.
  • Olson JS (1963). Energy storage and the balance of producers and decomposers in ecological systems. Ecology, 44: 322-331.
  • Risch AC, Ellis S, Wiswell H (2016). Where and why? Wood Ant Population Ecology. In: Stockan, J.A., Robinson, E.J.H. (Eds.), Wood Ant Ecology and Conservation. Cambridge, U.K.
  • Rosengren R, Fortelius W, Lindström K, Luther A (1987). Phenology and causation of nest heating and thermoregulation in red wood ants of the Formica rufa group studied in coniferous forest habitats in southern Finland. Annales Zoologici Fennici: 147-155.
  • Sarıyıldız T, Varan S, Duman A (2008). Ölü örtü ayrışma oranları üzerinde kimyasal bileşenlerin ve yetişme ortamı özelliklerinin etkisi: Artvin ve Ankara yöresine ait örnek bir çalışma. Kastamonu Ünivirsitesi Orman Fakültesi Dergisi, 8: 109-119.
  • SPSS (2011). IBM SPSS statistics base 20. SPSS Incorpo- rated, Chicago, IL.
  • Staaf H, Berg B (1981). Plant litter input to soil. In: Clark, F.E., Rosswall, T. (Eds.), Terrestrial nitrogen cycles. Processes, ecosystem strategies and management impacts. Ecological Bulletin pp. 147-167.
  • Stadler B, Schramm A, Kalbitz K (2006). Ant-mediated effects on spruce litter decomposition, solution chemistry, and microbial activity. Soil Biology and Biochemistry, 38: 561-572.
  • Stockan JA, Robinson EJ (2016). Wood ant ecology and conservation. Cambridge University Press,
  • Swift MJ, Heal W, Anderson JM (1979). Decomposition in Terrestrial Ecosystems. University of California Press, Berkeley.
  • Tolunay D (2009). Carbon concentrations of tree components, forest floor and understorey in young Pinus sylvestris stands in north-western Turkey. Scandinavian Journal of Forest Research, 24: 394-402.
  • Virzo De Santo A, Fierro A, Berg B, Rutigliano F, De Marco A (2002). Heavy metals and litter decomposition in coniferous forests. In: Violante, A., Huang, P.M., Bollag, J.M., Gianfreda, L. (Eds.), Developments in Soil Science. Elsevier pp. 63-78.
  • Voříšková J, Baldrian P (2013). Fungal community on decomposing leaf litter undergoes rapid successional changes. The ISME journal, 7: 477.
  • Wardle DA (2002). Communities and ecosystems: linking the aboveground and belowground components. Princeton University Press, Princeton.
  • Wardle DA, Hyodo F, Bardgett RD, Yeates GW, Nilsson M-C (2011). Long‐term aboveground and belowground consequences of red wood ant exclusion in boreal forest. Ecology, 92: 645-656.

The role of wood ants (Formica rufa group) on decomposition process: preliminary result

Year 2019, Volume: 21 Issue: 2, 477 - 485, 15.08.2019

Abstract

Wood ants (Formica rufa group)
are dominating ecosystem elements in coniferous forests of the temperate
region. They build the large nests on aboveground with organic material and
resin collected from the forest floor. These mounds have higher temperature and
lower water content than the surrounding forest floor. We studied how these
peculiar environmental conditions affected litter mass loss and carbon (C),
nitrogen (N), potassium (K), phosphor (P), manganese (Mn), iron (Fe) and
aluminium (Al) mineralisation of organic matter. The study conducted in
temperate Black pine (Pinus nigra
Arnold.) forest stands in Çankırı Karatekin University Faculty of Forestry
Research Forest using the litterbag technique. Black pine needle litter was
incubated in adjacent the wood ant nest and 10 m away from the nest edge.


While we expected decomposition to be slow due to the dryness of the
mounds and effect of wood ants, the ant nests were not found to have a
significant effect on the temporal variation of mass loss, carbon, nitrogen,
potassium and phosphorus in the process of litter decomposition. However, the
release of manganese, aluminium and iron is slower in ant nests compared to
forest soil.

Project Number

1919B011402186

References

  • Abay G, Ursavaş S (2009). Çankırı ili araştırma ormanı karayosunu (musci) flora ve ekolojisi. Bartın Orman Fakültesi Dergisi, 11: 61-70.
  • Aerts R (1997). Climate, leaf litter chemistry and leaf litter decomposition in terrestrial ecosystems: a triangular relationship. Oikos, 79: 439-449.
  • Berg B, Erhagen B, Johansson MB, Vesterdal L, Faituri M, Sanborn P, Nilsson M (2013). Manganese dynamics in decomposing needle and leaf litter—a synthesis. Canadian journal of forest research, 43: 1127-1136.
  • Berg B, McClaugherty C (2014). Plant litter, Decomposition, humus formation, carbon sequestration. Third Edition. Springer-Verlag, Berlin Heidelberg.
  • Berg B, Staaf H (1981). Leaching, acccumulation and release of nitrogen in decomposing forest litter. Terresterial Nitrogen Cycles. Ecological Bulletin, 33: 163-178.
  • Berg B, Steffen K, McClaugherty C (2007). Litter decomposition rate is dependent on litter Mn concentrations. Biogeochemistry, 82: 29-39.
  • Berger TW, Duboc O, Djukic I, Tatzber M, Gerzabek MH, Zehetner F (2015). Decomposition of beech (Fagus sylvatica) and pine (Pinus nigra) litter along an Alpine elevation gradient: decay and nutrient release. Geoderma, 251: 92-104.
  • Cammeraat E, Risch A (2008). The impact of ants on mineral soil properties and processes at different spatial scales. Journal of Applied Entomology, 132: 285-294.
  • Coleman DC, Crossley DA, Hendrix PF (2004). Fundamentals of soil ecology. Academic press, USA.
  • Çakır M, Akburak S (2017). Litterfall and nutrients return to soil in pure and mixed stands of oak and beech. Journal of The Faculty of Forestry Istanbul University, 67: 185-200.
  • Davey MP, Berg B, Emmett BA, Rowland P (2007). Decomposition of oak leaf litter is related to initial litter Mn concentrations. Botany, 85: 16-24.
  • Domisch T, Ohashi M, Finér L, Risch A, Sundström L, Kilpeläinen J, Niemelä P (2008). Decomposition of organic matter and nutrient mineralisation in wood ant (Formica rufa group) mounds in boreal coniferous forests of different age. Biology and Fertility of Soils, 44: 539-545.
  • Dutta RK, Agrawal MJP (2001). Litterfall, litter decomposition and nutrient release in five exotic plant species planted on coal mine spoils. 45: 298-312.
  • Frankland JC (1998). Fungal succession—unravelling the unpredictable. Mycological research, 102: 1-15.
  • Frouz J (2000). The effect of nest moisture on daily temperature regime in the nests of Formica polyctena wood ants. Insectes Sociaux, 47: 229-235.
  • Frouz J, Holec M, Kalčík J (2003). The effect of Lasius niger (Hymenoptera, Formicidae) ant nest on selected soil chemical properties. Pedobiologia, 47: 205-212.
  • Frouz J, Jílková V, Sorvari J (2016). Contribution of wood ants to nutrient cycling and ecosystem function. In: Stockan, J.A., Robinson, E.J.H. (Eds.), Wood Ant Ecology and Conservation. Cambridge University Press, U.K., p. 207.
  • Frouz J, Kalčík J, Cudlín P (2005). Accumulation of phosphorus in nests of red wood ants Formica s. str. Annales Zoologici Fennici, 42: 269-275.
  • Goya JF, Frangi JL, Pérez CA, Dalla Tea F (2008). Decomposition and nutrient release from leaf litter in Eucalyptus grandis plantations on three different soils in Entre Ríos, Argentina. Bosque, 29.
  • Göl C, Yılmaz H, Ediş S (2010). Orman fakültesi araştırma ve uygulama ormanı topraklarının bazı özellikleri ve sınıflandırması. In, III. Ulusal Karadeniz Ormancılık Kongresi, Artvin, pp. 941-952.
  • Güner Ş, Çömez A (2017). Biomass equations and changes in carbon stock in afforested black pine (Pinus nigra Arnold. subsp. pallasiana (Lamb.) Holmboe) stands in Turkey. Fresenius Environmental Bulletin, 26: 2368-2379.
  • Hoorens B, Aerts R, Stroetenga M (2003). Does initial litter chemistry explain litter mixture effects on decomposition? Oecologia, 137: 578-586.
  • Jílková V, Cajthaml T, Frouz J (2018). Relative importance of honeydew and resin for the microbial activity in wood ant nest and forest floor substrate–a laboratory study. Soil Biology Biochemistry, 117: 1-4.
  • Jílková V, Matějíček L, Frouz J (2011). Changes in the pH and other soil chemical parameters in soil surrounding wood ant (Formica polyctena) nests. European Journal of Soil Biology, 47: 72-76.
  • Jílková V, Šebek O, Frouz J (2012). Mechanisms of pH change in wood ant (Formica polyctena) nests. Pedobiologia, 55: 247-251.
  • Jurgensen M, Finer L, Domisch T, Kilpeläinen J, Punttila P, Ohashi M, Niemelä P, Sundström L, Neuvonen S, Risch A (2008). Organic mound‐building ants: their impact on soil properties in temperate and boreal forests. Journal of Applied Entomology, 132: 266-275.
  • Kilpeläinen J, Finér L, Niemelä P, Domisch T, Neuvonen S, Ohashi M, Risch A, Sundström L (2007). Carbon, nitrogen and phosphorus dynamics of ant mounds (Formica rufa group) in managed boreal forests of different successional stages. Applied Soil Ecology, 36: 156-163.
  • Kristiansen S, Amelung W (2001). Abandoned anthills of Formica polyctena and soil heterogeneity in a temperate deciduous forest: morphology and organic matter composition. European Journal of Soil Science, 52: 355-363.
  • Laakso J, Setälä H (1997). Nest mounds of red wood ants (Formica aquilonia): hot spots for litter-dwelling earthworms. Oecologia, 111: 565-569.
  • Laakso J, Setälä H (1998). Composition and trophic structure of detrital food web in ant nest mounds of Formica aquilonia and in the surrounding forest soil. Oikos: 266-278.
  • Laakso J, Setälä H (2000). Impacts of wood ants (Formica aquilonia Yarr.) on the invertebrate food web of the boreal forest floor. Annales Zoologici Fennici, 37: 93-100.
  • Lenoir L, Bengtsson J, Persson T (2003). Effects of Formica ants on soil fauna-results from a short-term exclusion and a long-term natural experiment. Oecologia, 134: 423-430.
  • Lenoir L, Persson T, Bengtsson J (2001). Wood ant nests as potential hot spots for carbon and nitrogen mineralisation. Biology and fertility of Soils, 34: 235-240.
  • Manzoni S, Trofymow JA, Jackson RB, Porporato A (2010). Stoichiometric controls on carbon, nitrogen, and phosphorus dynamics in decomposing litter. Ecological Monographs, 80: 89-106.
  • Nkem JN, Lobry de Bruyn LA, Grant CD, Hulugalle NR (2000). The impact of ant bioturbation and foraging activities on surrounding soil properties. Pedobiologia, 44: 609-621.
  • Olson JS (1963). Energy storage and the balance of producers and decomposers in ecological systems. Ecology, 44: 322-331.
  • Risch AC, Ellis S, Wiswell H (2016). Where and why? Wood Ant Population Ecology. In: Stockan, J.A., Robinson, E.J.H. (Eds.), Wood Ant Ecology and Conservation. Cambridge, U.K.
  • Rosengren R, Fortelius W, Lindström K, Luther A (1987). Phenology and causation of nest heating and thermoregulation in red wood ants of the Formica rufa group studied in coniferous forest habitats in southern Finland. Annales Zoologici Fennici: 147-155.
  • Sarıyıldız T, Varan S, Duman A (2008). Ölü örtü ayrışma oranları üzerinde kimyasal bileşenlerin ve yetişme ortamı özelliklerinin etkisi: Artvin ve Ankara yöresine ait örnek bir çalışma. Kastamonu Ünivirsitesi Orman Fakültesi Dergisi, 8: 109-119.
  • SPSS (2011). IBM SPSS statistics base 20. SPSS Incorpo- rated, Chicago, IL.
  • Staaf H, Berg B (1981). Plant litter input to soil. In: Clark, F.E., Rosswall, T. (Eds.), Terrestrial nitrogen cycles. Processes, ecosystem strategies and management impacts. Ecological Bulletin pp. 147-167.
  • Stadler B, Schramm A, Kalbitz K (2006). Ant-mediated effects on spruce litter decomposition, solution chemistry, and microbial activity. Soil Biology and Biochemistry, 38: 561-572.
  • Stockan JA, Robinson EJ (2016). Wood ant ecology and conservation. Cambridge University Press,
  • Swift MJ, Heal W, Anderson JM (1979). Decomposition in Terrestrial Ecosystems. University of California Press, Berkeley.
  • Tolunay D (2009). Carbon concentrations of tree components, forest floor and understorey in young Pinus sylvestris stands in north-western Turkey. Scandinavian Journal of Forest Research, 24: 394-402.
  • Virzo De Santo A, Fierro A, Berg B, Rutigliano F, De Marco A (2002). Heavy metals and litter decomposition in coniferous forests. In: Violante, A., Huang, P.M., Bollag, J.M., Gianfreda, L. (Eds.), Developments in Soil Science. Elsevier pp. 63-78.
  • Voříšková J, Baldrian P (2013). Fungal community on decomposing leaf litter undergoes rapid successional changes. The ISME journal, 7: 477.
  • Wardle DA (2002). Communities and ecosystems: linking the aboveground and belowground components. Princeton University Press, Princeton.
  • Wardle DA, Hyodo F, Bardgett RD, Yeates GW, Nilsson M-C (2011). Long‐term aboveground and belowground consequences of red wood ant exclusion in boreal forest. Ecology, 92: 645-656.
There are 49 citations in total.

Details

Primary Language Turkish
Subjects Forest Industry Engineering
Journal Section Biodiversity, Environmental Management and Policy, Sustainable Forestry
Authors

Meriç Çakır 0000-0001-8402-5114

Tuğba Tunç This is me 0000-0002-6291-4751

Project Number 1919B011402186
Publication Date August 15, 2019
Published in Issue Year 2019 Volume: 21 Issue: 2

Cite

APA Çakır, M., & Tunç, T. (2019). Ayrışma Sürecinde Orman Karıncalarının (Formica rufa grup) Rolü: İlk Yıl Sonuçları. Bartın Orman Fakültesi Dergisi, 21(2), 477-485.


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