Influence of soil compaction on the growth of silver fir (Abies alba Mill.) under a forest canopy
DOI:
https://doi.org/10.12775/EQ.2015.022Keywords
compaction, pressure compaction unit, seedling, silver fir.Abstract
In the study, the influence of soil compaction on the growth of silver fir seedlings (Abies alba Mill.) was evaluated; the soil compaction being measured using a cone penetrometer. The studies were conducted under a forest canopy, where the exploratory units with different soil compactions exerting a unit pressure of 50, 100, 150, 200, and 250 kPa, as well as the control units (without pressure), were prepared. Selected units were sown with seeds of silver fir, and from the remaining units, the soil samples were collected and their compaction measured using a cone penetrometer. After 5 months, the seedlings were collected and their growth analyzed. Increasing the unit pressure resulted in soil compaction characterized by the compaction in the layer up to 15 cm, in which the roots of the growing seedlings were found. Different variants of the pressure significantly affected the analyzed parameters of seedlings. Negative and statistically significant correlation was reported between increasing compaction of the soil, the length of the primary root, and the total length of seedlings (-0.46 and -0.35, respectively), while the positive correlation was found for the length of the stem (+0.32). Similarly, there was a statistically significant negative correlation between the increased soil compaction and the dry weight of the root system (-0.29), and positive correlation in the case of the stem dry weight (0.26). Increasing soil compaction, however, did not affect significantly the size of assimilation apparatus.
References
ASAE Standards, 1998, Soil Cone Penetrometer, [in:] Standards Engineering Practices Data, American Society of Agricultural Engineers, 820–821.
Alameda D., Anten N. P. R. & Villar R., 2012, Soil compaction effects on growth and root traits of tobacco depend on light, water regime and mechanical stress, Soil & Tillage Research 120: 121–129.
Blouin V. M., Schmidt M. G., Bulmer C.E. & Krzic M., 2008, Effects of compaction and water content on lodgepole pine sidling growth, Forest Ecology and Management 255: 2444–2452.
Bejarano M.D., Villar R., Murillo A.M. & Quero J. L., 2010, Effects of soil compaction and light on growth of Quercus pyrenaica Willd. (Fagaceae) seedlings, Soil & Tillage Research 110: 108–114.
Conlin T.S.S. & van den Driessche R., 1996, Short term effects of soil compaction on growth of Pinus contorta seedlings, Canadian Journal of Forest Research 26: 727–739.
Corns I.G.W., 1988, Compaction by forestry equipment and effects on coniferous seedling growth on four soils in the Alberta foothills, Canadian Journal of Forest Research 18: 75–84.
Dexter A.E., Czyż E.A. & Gate O.P., 2007, A method for prediction of soil penetration resistance, Soil & Tillage Research 93 (2): 412–419.
Kormanek M., 2011, Mobile hand -held cone penetrometer with data logger, Polish patent application: P.397565.
Kormanek M., 2013, Tractor device to exert controlled pressure on the ground, Polish utility model: W.120048.
Kormanek M. & Banach J., 2012, Influence of unit pressure exerted on soil on quality of renewal of chosen species of trees, Acta Agrophysica 19(1): 51–63.
Kormanek M., Banach J. & Ryba M. 2013, Influence of substrate compaction in nursery containers on the growth of Scots pine (Pinus sylvestris L.) seedlings, Leśne Prace Badawcze 74 (4): 307–314.
Kozlowski T. 1999, Soil compaction and growth of woody plants, Scandinavian Journal of Forest Research 14: 596–619.
Lipiec J., Hajnos M. & Świeboda R., 2012, Estimating effects of compaction on pore size distribution of soil aggregates by merkury porosimeter, Geoderma 179-180: 20–27.
Maupin C. & Struve D.K., 1997, Red oak transplanting to different bulk density soils have similar water use characteristics, Journal of Arboriculture 23: 233–238.
Pérez-Ramos, I.M., Gómez-Aparicio, L., Villar, R., García, L.V. & Marañón, T., 2010, Seedling growth and morphology of three oak species along field resource gradients and seed-mass variation: a seedling-age-dependent response, J. Veg. Sci. 21: 419–437.
PTG, 2008, Klasyfikacja uziarnienia gleb i utworów mineralnych [Classification of grain-size composition of soils and mineral sediments], Polish Society of Soil Science.
Picchio R., Neri F., Petrini E., Verani S., Marchi E. & Certini G., 2012, Machinery-induced soil compaction in thinning two pine stands in central Italy, Forest Ecology and Management 285: 38–43.
Sack L., 2004, Responses of temperate woody seedlings to shade and drought: dotrade-offs limit potential niche differentiation?, Oikos 107: 110–127.
Sands R. & Bowen G.D., 1978, Compaction of sandy soil in radiate pine forests. 2. Effects of compaction on root configuration and growth of radiata pine seedlings, Australian Forest Research 8: 163–170.
Sobczak R. (ed.), 1992, Szkółkarstwo leśne [Forest tree seedling nursery], Wydawnictwo Świat, Warszawa.
Ulrich R., Neruda J. & Valenta J., 2003, Wpływ układów jezdnych wybranych maszyn maszyn na glebę [Effects of the machines running gears on soil], Inżynieria Rolnicza 7(11): 229–235.
Watson G.W. & Kelsey P., 2006, The impact of soil compaction on soil aeration and fine root density of Quercus palustris, Urban Forestry & Urban greening 4: 69 -74.
Zahreddine H.G., Struve D.K. & Quigley M., 2004, Growing Pinus nigra seedlings in Spinout-treated containers reduces root malformation and increases regrowth potential, Journal of Environmental Horticulture 22:176–182.
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