Deciphering the history of forest disturbance and its effects on landforms and soils – lessons from a pit-and-mound locality at Rogowa Kopa, Sudetes, SW Poland
DOI:
https://doi.org/10.1515/bgeo-2017-0006Keywords
forest biogeomorphology, pit-mound topography, tree uprooting, soils, dendrochronology, SudetesAbstract
The historical dimension of pit-and-mound topography has been studied at Mt Rogowa Kopa locality, Stołowe Mountains, SW Poland. This site represents one of the best developed regional examples of hummocky forest floor relief due to widespread tree uprooting and subsequent degradation of root plates. Through map analysis and dendrochronology the disturbance history was traced at least to the 1930s and most likely a strong wind episode from 1933 was the reason of forest calamity that resulted in nearly complete destruction of the original stand. However, the forest affected was a planted Norway spruce monoculture, introduced and managed at least till the beginning of 20th century, not a natural forest. The windthrow niche was then used by beech whose individuals preferentially chose mounds to grow, conserving hummocky microtopography. Changes in soil evolutionary pathways brought about by wind-driven disturbance include both homogenization (rejuvenation) and horizonation (differentiation). Evidence of soil rejuvenation includes decrease of organic carbon content and pH increase in the upper parts of soils developed on mounds in comparison with undisturbed references soils. Soil texture was relatively homogenized in pits and mounds. Dating of pit-and-mound microrelief by means of soil properties (organic carbon content, iron forms) was only partly successful. Although young age of pits and mounds is evident, the actual age inferred from soil properties was underestimated by a few tens of years. Evaluation of factors potentially controlling the propensity to widespread treethrow suggests that the type of forest is a far more important variable than local abiotic factors of bedrock geology, regolith characteristics, and slope inclination.References
Amundson, R., Heimsath, A., Owen, J., Yoo, K., Dietrich, W.E., 2015, Hillslope soils and vegetation. Geomorphology, 234, 122-132.
Beaudette, D.E, Roudier, P., O’Geen, A.T., 2013, Algorithms for quantitative pedology: A toolkit for soil scientists. Computers & Geosciences, 52, 258-268.
Beke, G.J., McKeague, J.A., 1984, Influence of tree windthrow on the properties and classification of selected forested soils from Nova Scotia. Can. J. Soil Sci., 64, 195–207.
Bobrovsky, M.V., Loyko, S.V., 2016, Patterns of pedoturbation by tree uprooting in forest soils. Russian Journal of Ecosystem Ecology, 1, 1-22.
Borecki, T., Wójcik, R., 1996, Stopień uszkodzenia drzewostanów Parku Narodowego Gór Stołowych. Szczeliniec, 1, 167-169.
Bradshaw, R.H.W., Kito, N., Giesecke, T, 2010, Factors influencing the Holocene history of Fagus. Forest Ecology and Management, 259, 2204-2212.
Brázdil, R., 1998, Meteorological extremes and their impacts on forests in the Czech Republic, [in:] Beniston, M., Innes, J.L. (eds.), The impacts of climate variability on forests. Springer-Verlag, Berlin, Heidelberg, New York, pp. 19-47.
Denny, Ch.S., Goodlett, J.C., 1956, Microrelief resulting from fallen trees. USGS Prof. Publ., 288, 59-68.
Dinno, A., 2016, Dunn’s Test of Multiple Comparisons Using Rank Sums. WWW: https://cran.r-project.org.
Dubicki, A., Głowicki, B., 2008, Climate, [in:] Witkowski, A., Pokryszko, B.M., Ciężkowski, W. (eds.), Przyroda Parku Narodowego Gór Stołowych, Wydawnictwo Parku Narodowego Gór Stołowych, pp. 49–69.
Dümig, A., Smittenberg, R., Kögel-Knabner, I., 2011, Concurrent evolution of organic and mineral components during initial soil development after retreat of the Damma glacier, Switzerland. Geoderma, 163, 83–94.
Egli, M., Favilli, F., Krebs, R., Pichler, B., Dahms, D., 2012, Soil organic carbon and nitrogen accumulation rates in cold and alpine environments over 1 Ma. Geoderma, 183–184, 109–123.
Everham, E.M., Brokaw, N.V., 1996, Forest damage and recovery from catastrophic wind. The Botanical Review, 62, 113-185.
Gabet, E.J., Mudd, S.M., 2010, Bedrock erosion by root fracture and tree throw: a coupled biogeomorphic model to explore the humped soil production function and the persistence of hillslope soils. Journal of Geophysical Research—Earth Surface, 115, F04005.
Gee, G. W., Bauder, J. W., 1986, Particle-size analysis, in: Klute, A. (ed.), Methods of Soil Analysis, Part 1: Physical and Mineralogical Methods–Agronomy Monograph No. 9, 2nd edition. ASA–SSSA, Madison, WI, USA, pp. 383–411.
Grissino-Mayer, H.D, 2001, Evaluating crossdating accuracy: a manual and tutorial for the computer program Cofecha. Tree-ring Research, 57, p. 205-221.
Holmes, R.L., 1983, Computer-assisted quality control in tree-ring dating and measurement. Tree-Ring Bulletin, 43, 69-78.
Jahn, R., Blume, H.-P., Asio, V.B., Spaargaren, O., Schad, P., 2006, Guidelines for soil description, 4th edition. FAO, Rome, Italy.
Jaworski, A., Pach, M., 2014, A comparison of lower montane natural forest (Abies, Fagus, Picea) in Oszast Reserve and spruce monocultures in the Żywiecki Beskid and Śląski Beskid. Forest Research Papers, 75, 13-23.
Johnson, D.L., Watson-Stegner, D., Johnson, D.N., Schaetzl, R.J., 1987, Proisotropic and proanisotropic processes of pedoturbation. Soil Sci., 143, 278-292.
Kabała, C., Szerszeń, L., Wicik, B., 2002, Geneza, właściwości i systematyka gleb Parku Narodowego Gór Stołowych. Szczeliniec, 6, 21-94.
Lorimer, C.G., Frelich, L.E., 1989, A methodology for estimating canopy disturbance frequency and intensity in dense temperate forests. Can. J. For. Res., 19, 651-663.
Mazurski, K.R., 1986, The destruction of forests in the Polish Sudetes Mountains by industrial emissions. Forest Ecology and Management, 17, 303-315.
Mehra, O.P., Jackson, M.L., 1960, Iron oxide removal from soils and Clay by dithionite– citrate systems bufered with sodium bicarbonate. Clays Clay Miner., 73, 73–80.
Migoń, P., Kasprzak, M., 2015, Pathways of geomorphic evolution of sandstone escarpments in the Góry Stołowe tableland (SW Poland) – Insights from LiDAR-based high-resolution DEM. Geomorphology. doi:10.1016/j.geomorph.2015.08.022.
Miścicki, S., 2008, Forest (in Polish), [in:] Witkowski, A., Pokryszko, B.M., Ciężkowski, W. (eds.), Przyroda Parku Narodowego Gór Stołowych, Wydawnictwo PNGS, Kudowa-Zdrój, pp. 304-321.
Mitchell, S.J., 2012, Wind as a natural disturbance agent in forests: a synthesis. Forestry, 86, 147-157.
Nowacki, G.J., Abrams, M.D., 1997, Radial-growth averaging criteria for reconstructing disturbance histories from presettlement-origin oaks. Ecological Monographs, 67, 225-249.
Ogle, D., 2016, Introductory Fisheries analyses with R. Chapman&Hall/CRC, Boca Raton, FL.
Paulson, T.L., Platt, W.J., 1996, Replacement patterns of beech and sugar maple in Warren Woods, Michigan. Ecology, 77, 1234-1253.
Pawlik, Ł., 2012, Forest damage in the Sudety Mts. caused by the Kyrill storm (18-19.01.2007) – historic and regional implications (in Polish, with English summary). Przegląd Geograficzny, 84, 53-75.
Pawlik, Ł., Kasprzak, M., 2015, Electrical resistivity tomography (ERT) of pit-and-mound microrelief, Mt Rogowa Kopa case study, the Stołowe Mountains, SW Poland. Landform Analysis, 29, 41-47.
Pawlik, Ł., Migoń, P., Owczarek, P., Kacprzak, A., 2013, Surface processes and interactions with forest vegetation on a steep mudstone slope, Stołowe Mountains, SW Poland. Catena, 109, 203-216.
Pawlik, Ł., Migoń, P., Szymanowski, M., 2016, Local- and regional-scale biomorphodynamics due to tree uprooting in semi-natural and manager montane forests of the Sudetes Mountains, Central Europe. Earth Surface Processes and Landforms, 41, 1250-1265.
Pawluk, S., Dudas, M.J., 1982, Floralpedoturbations in Black Chernozemic soils of the Lake Edmonton Plain. Canadian Journal of Soil Science, 62, 617-629.
Phillips, J.D., Marion, D.A., 2006, The biomechanical effects of trees on soils and regoliths: beyond treethrow. Annals of the Association of American Geographers, 96, 233-247.
Phillips, J.D., Marion, D.A., Turkington, A.V., 2008, Pedologic and geomorphic impacts of a tornado blowdown event in a mixed pine-hardwood forest, Catena, 75, 278-287.
Phillips, J.D., Samonil, P., Pawlik, Ł., Trochta, J., Danek, P., 2017, Domination of Hillslope Denudation by Tree Uprooting in an Old-Growth Forest. Geomorphology, 276, 27-36.
van Reeuwijk, L.P., 2002, Procedures for soil analysis, six edition, ISRIC, Technical Paper 9, Wageningen.
Roering, J.J., Marshall, J., Booth, A.M., Mort, M., Jin, Q., 2010, Evidence for biotic controls on topography and soil production. Earth Planet. Sci. Lett., 298, 183-190.
Rotnicka, J., 1996, The age and lithology of so called planar marls (in Polish). Szczeliniec, 21-26.
Schaetzl, R.J., 1986, Complete soil profile inversion by tree uprooting. Phys. Geogr., 7, 181-189.
Schaetzl, R.J., 1990, Effects of treethrow microtopography on the characteristics and genesis of Spodosols, Michigan, USA. Catena, 17, 111–126.
Schaetzl, R.J., Thompson, M.L., 2015, Soils: genesis and geomorphology, second ed. Cambridge University Press, UK.
Schaetzl, R.J., Burns, S.F., Small, T.W., Johnson, D.L., 1990, Tree uprooting: review of types and patterns of soil disturbances. Physical Geography, 11, 277-291.
Schwertmann, U., 1964, Differenzierung der Eisenoxide des Bodens durch Extraction mit Ammoniumoxalat-Lösung. Zeitschrift für Pflanzenemährung Düngung Bodenkunde. 105, 194–202.
Stephens, E.P., 1956, The uprooting of trees: A forest process. Soil Sci. Soc. Am. Proc., 20, 113-116.
Świerkosz, K., Boratyński, A., 2002, Chorological and synanthropodynamical analysis of trees and shrubs of the Stołowe Mts. (Middle Sudety). Dendrobiology, 48, 75-85.
Šamonil, P., Král, K., Hort, L., 2010a, The role of tree uprooting in soil formation: A critical literature review. Geoderma, 157, 65-79.
Šamonil, P., Tejnecký, V., Borůvka, L., Šebková, B., Janík, D., Šebek, O., 2010b, The role of tree uprooting in Cambisol development. Geoderma, 159, 83–98.
Šamonil, P., Schaetzl, R.J., Valtera, M., Golias, V., Baldrian, P., Vašíčková, I., Adam, D., Janik, D., Hort, L., 2013, Crossdating of disturbances by tree uprooting: Can treethrow microtopography persist for 6,000 years? Forest Ecology and Management, 307, 123-135.
Šamonil, P., Vašíčková, I., Daněk, P., Janík, D., Adam, D., 2014, Disturbances can control fine-scale pedodiversity in old-growth forests: is the soil evolution theory disturbed as well? Biogeosciences, 11, 5889-5905, doi: 10.5194/bg-11-5889-2014.
Šamonil, P., Daněk, P., Schaetzl, R.J., Vašíčková, I., Valtera, M., 2015, Soil mixing and genesis as affected by tree uprooting in three temperate forests. European Journal of Soil Science, 66, 589-603.
Šebková, B., Šamonil, P., Valtera, M., Adam, D., Janík, D., 2012, Interactions between tree species populations and windthrow dynamics in natural beech-dominated forest, Czech Republic. Forest Ecology and Management, 280, 9-19.
SMNP, 2009, Stołowe Mountains National Park Forest Survey Report, Unpublished report, Kudowa Zdrój, Poland.
Thomas, G.W., 1996, Soil pH and soil acidity, In: Sparks, D.L. et al. (eds.), Methods of Soil Analysis, Part 3: Chemical Methods – SSSA Book Series No. 5. SSSA and ASA, Madison, WI, USA, pp. 475–490.
Trotsiuk, V., Hobi, M.L., Commarmot, B., 2012, Age structure and disturbance dynamics of the relic virgin beech forest Uholka (Ukrainian Carpathians). Forest Ecology and Management, 265, 181-190.
Veneman. P.L.M., Jacke. P.V., Bodine. S.M., 1984, Soil formation as affected by pit and mound microrelief in Massachusetts, U.S.A. Geoderma, 33, 89-99.
Wei, T., Simko, V., 2016, Corrplot: Visualization of a Correlation Matrix. WWW: https://CRAN.R-project.org/package=corrplot.
Wickham, H., Chang, W., 2016, An implementation of the grammar of graphics. WWW: http://ggplot2.org/.
Wojda, M., Zaborski, S., 1959, Szkody wyrządzone przez huragan w dniu 17.I.1955 r. na terenie leśnictwa Piekiełko w Górach Bystrzyckich (in Polish). Zeszyty Naukowe SGGW w Warszawie, Leśnictwo, Zeszyt 2, 43-55.
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