The long-term changes of forest communities as an effect of former iron-ore mining activities and current forest management: importance for local biodiversity

• Autorzy: Podgorska M.
• Języki publikacji: EN

Abstrakty

EN

The human induced changes affect the transformation of different plant communities. In some cases this process can contribute to increase in local biodiversity, but it depends on type and manner of human activity involved. The main aim of this study is to answer the question how two anthropogenic factors (former and current) can modify the species composition in forest phytocoenoses. The study area is situated in the southern Poland (Małopolska Upland). The studies were carried out on two former (19th century) mining fields where planting Common Beech Fagus sylvatica (field A) and Scots Pine Pinus sylvestris (field B) have been done since the first half of the 20th century. On gob piles (sites transformed by former iron-ore mining), single-species beech (field A) or pine (field B) tree stands are undergoing secondary succession, and transform into multi-species, fertile deciduous forests. This secondary communities corresponding to the types of new, fertile soils (formed by clayey-loamy material of gob piles), generated as a result of mining activities. Whereas, on non-transformed areas forest communities with floristic structures and composition linked to poor and acidophilous phytocoenoses developed. These communities are also compatible with their respective, primary habitats (acid, poor, and sandy soils). Nonetheless, the secondary succession of forest communities on gob piles can be disturbed. In the herb layer of fertile habitats of post-mining sites where Pinus sylverstis was planted (field B) acidophilous species among mesophilous forest species were noted. This process of acidification of humus layer is induced by the fall of needles of pines and it has not been observed in communities with planted Fagus sylvatica (field A). It was found that previous mining activities now affect the secondary succession in the forest communities of northern part of the Małopolska Upland because they have created new habitats where process of forming mesophilous phytocoenoses was observed. Accordingly, former human activity leads to the increase in local biodiversity. On the other side current forest management can reduce this effect as a result of planting tree species which acidify these fertile habitats and suppressed the occurrence of mesophilous forest species, what, by contrast, decrease the species richness.

Słowa kluczowe

EN

plant community; forest structure; biodiversity; human activity; floristic composition; mining industry; mining activity; forest management; Fagus sylvatica; beech; Scotch pine; Pinus sylvestris; secondary succession; soil condition; Malopolska Upland

• Wydawca: -
• Czasopismo: Polish Journal of Ecology
• Rocznik: 2016
• Tom: 64
• Numer: 1
• Opis fizyczny: p.35-44,fig.,ref.

Twórcy

autor

Podgorska M.

• Department of Environment Protection and Modelling, The Jan Kochanowski University, Swietokrzyska 15, 25-406 Kielce, Poland

Bibliografia

• Bzdon G. 2008 — Gravel pits as habitat islands: floristic diversity and vegetation analysis — Pol. J. Ecol. 56: 239–250.
• Closset-Kopp D., Schnitzler A., Aran D. 2006 — Dynamics in natural mixed-beech forest of the Upper Vosges — Biodivers. Conserv. 15: 1063–1093.
• Decocq G. 2000 — The ’masking effect’ of silviculture on substrate-induced plant diversity in oak-hornbeam forests from northern France — Biodivers. Conserv. 9: 1467–1491.
• Dzwonko Z. 2007 — Przewodnik do badań fitosocjologicznych [Guide for phytosociological research] — Sorus, Poznań-Kraków, 302 pp. (in Polish).
• Galera H., Sudnik-Wójcikowska B., Wierzbicka M., Wiłkomirski B. 2011 — Encroachment of forest species into operating and abandoned railway areas in north-eastern Poland — Plant Biosyst. 145: 23–36.
• Godzik B. 2015 — Natural and historical values of the Olkusz Ore-bearing Region — W. Szafer Institute of Botany, Polish Academy of Sciences, Kraków, 334 pp.
• Johnson M.S. 1978 — Land reclamation and the botanical significance of some former mining and manufacturing sites in Britain — Environ. Conserv. 5: 223–228.
• Kleczkowski A. 1970 — Rudy żelaza w utworach pstrego piaskowca północnego obrzeżenia Gór Świętokrzyskich [Iron ores in the Bunter deposits of the northern margins of the Góry Świętokrzyskie] — Prace Muz. Ziemi 15: 193–221 (in Polish).
• Li S., Yang B., Wu D. 2008 — Community succession analysis of naturally colonized plants on coal gob piles in Shanxi Mining Areas, China — Water Air Soil Poll. 193: 211–228.
• Lust N., Muys B., Nachtergale L. 1998 — Increase of biodiversity in homogenous Scots pine stands by an ecologically diversified management — Biodivers. Conserv. 7: 249–260.
• Matuszkiewicz W. 2011 — Przewodnik do oznaczania zbiorowisk roślinnych Polski [Guide for indication of plant communities of Poland] Vademecum Geobotanicum 3 — Wydawnictwa Naukowe PWN, Warszawa, 536 pp. (in Polish).
• Medwecka-Kornaś A. 2011 — The association Pino-Quercetum in the past and at present in the forest ’Las Wolski’ (Kraków, Southern Poland) (In: Geobotanist and Taxonomist, Ed: B. Zemanek) — Institute of Botany, Jagiellonian University, Cracow, pp. 91–115.
• Mirek Z., Piękoś-Mirkowa H., Zając A., Zając M. 2002 — Flowering plants and pteridophytes of Poland — a checklist (In: Biodiversity of Poland 1, Ed: Z. Mirek) — W. Szafer Institute of Botany, Polish Academy of Sciences, Kraków, pp. 1–442.
• Pierściński P. 2001 — Old Polish Industrial District — Sam-Wil, Kielce. pp. 136.
• Podgórska M. 2010 — The impact of former iron ore mining on the transformation of vegetation cover of the Gielniowski Hump (Małopolska Upland) — Biodiv. Res. Conserv. 17: 53–62.
• Podgórska M. 2011a — Projekt utworzenia stanowiska dokumentacyjnego w okolicy Sowiej Góry na Garbie Gielniowskim (Wyżyna Małopolska) [Proposed documentary station in the vicinity of Sowia Góra in the Gielniowski Hummock (Małopolska Upland)] — Prob. Ekol. Kraj. 29: 199–205 (in Polish).
• Podgórska M. 2011b — Flora roślin naczyniowych Garbu Gielniowskiego [The vascular plants flora of the Gielniowski Hummock (Małopolska Upland)] — Prace Botaniczne, 44: 1–304 (in Polish).
• Podgórska M. 2015 — Specific remnants of old iron-ore extraction sites as islands of plant species richness — Open Life Sci. 10: 182–194.
• StatSoft. 2003 — STATISTICA (data analysis software system), version 6.1 — StatSoft, Inc., Tulsa, OK.
• Titlyanova A.A., Mironycheva-Tokareva N.P. 1990 — Vegetation succession and biological turnover on coal-mining spoils — J. Veg. Sci. 1: 643–652.
• Tokarska-Guzik B.1996 — Rola hałd zasadowych w utrzymaniu lokalnej bioróżnorodności [A role of alkaline heaps in maintenance of local biodiversity] — Przegl. Przyr. 7: 261–266.
• Woźniak G., Pasierbiński A., Rostański A. 2003. The diversity of spontaneous woodland vegetation on coals mine heaps of Upper Silesia Region — Arch. Ochr. Środ. 29: 93–105.

Identyfikatory

DOI

10.3161/15052249PJE2016.64.1.004