The influence of hydrogel soil amendment on the survival and growth of newly transplanted Pinus patula seedlings

Ada Mudhanganyi; Hilton G. T. Ndagurwa; Carlton Maravanyika; Robert Mwase

doi:10.1007/s11676-017-0428-1

Journal of Forestry Research ›› 2017, Vol. 29 ›› Issue (1) : 103 -109. DOI: 10.1007/s11676-017-0428-1

Original Paper

The influence of hydrogel soil amendment on the survival and growth of newly transplanted Pinus patula seedlings

Author information +

History +

PDF

Abstract

Hydrogel amendments have been used to improve seedling survival and establishment particularly in dry environments. However, their effect on survival and growth of newly transplanted seedlings under varying water stress conditions is poorly known. In this regard, we examined the effects of Aqua Matrix Forestry^®, a potassium-based water-absorbent polymer, on the survival and early growth of Pinus patula seedlings planted in early-, mid- and late-dry season in the eastern highlands of Zimbabwe. The late-dry season was hotter and received more rainfall than the early- and mid-dry season. Hydrogel increased seedling survival by 34 and 22% in the mid- and late-dry season, respectively. Also, hydrogel-treated seedlings were significantly taller than untreated seedlings (P < 0.001). The height to root collar diameter ratio of hydrogel-treated seedlings was greater than that of untreated seedlings only in the mid-dry season. In conclusion, increase in survival and early growth of hydrogel-treated seedlings suggests that hydrogels can be used to extend planting beyond the rainy season to include the dry months, a feat previously unattainable due to high seedling mortality. Further, these findings reflect similar findings with other hydrogels, suggesting that improved seedling survival and plant performance may be a general consequence of hydrogel amendments.

Keywords

Hydrogel / Pinus patula / Reforestation / Seedling / Survival

Cite this article

Download citation ▾

Ada Mudhanganyi, Hilton G. T. Ndagurwa, Carlton Maravanyika, Robert Mwase. The influence of hydrogel soil amendment on the survival and growth of newly transplanted Pinus patula seedlings. Journal of Forestry Research, 2017, 29(1): 103-109 DOI:10.1007/s11676-017-0428-1

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Akhter J, Mahmood K, Malik KA, Mardan A, Ahmad M, Iqbal MM. Effects of hydrogel amendment on water storage of sandy loam and loam soils and seedlings growth of barley, wheat and chickpea. Plant Soil Environ, 2004, 50: 463-469.

[2]	Alm A, Stanton J. Polymer root dip increases survival of stressed bareroot seedlings. North J Appl For, 1993, 10: 90-92.

[3]	Apostol KG, Jacobs DF, Dumroese RK. Root desiccation and drought stress responses of bareroot Quercus rubra seedlings treated with a hydrophilic polymer root dip. Plant Soil, 2009, 315: 229-240.

[4]	Bayley AD, Kietzka JW. Stock quality and field performance of Pinus patula seedlings produced under two nursery growing regimes during seven different nursery production periods. New For, 1996, 13: 337-352.

[5]	Birks JS, Barnes RD (1991) Genetic control of wood quality in Pinus panda. In: Final report. UK: ODA research scheme R4616, Oxford University Press, Oxford Forestry Institute, p 29

[6]

Boko M, Niang I, Nyong A, Vogel C, Githeko A, Medany M, Osman-Elasha B Parry ML, Canziani OF, Palutikof JP, van der Linden PJ, Hanson CE Africa climate change: impacts, adaptation and vulnerability. Contribution of working group II to the fourth assessment report of the intergovernmental panel on climate change, 2007, Cambridge: Cambridge University Press 433 467

[7]	Bouranis DL, Theodoropoulus AG, Drossopoulus JB. Designing synthetic polymers as soil conditioners. Commun Soil Sci Plant Anal, 1995, 26: 1455-1480.

[8]	Burdett AN. Physiological processes in plantation establishment and the development of specifications for forest planting stock. Can J For Res, 1990, 20: 415-427.

[9]	Callaghan TV, Abdelnour H, Lindley DK. The environmental crisis in the Sudan: the effect of water-absorbing synthetic polymers on tree germination and early survival. J Arid Environ, 1988, 14: 301-317.

[10]	Callaghan TV, Lindley DK, Ali OM, El Nour HA, Bacon PJ. The effect of water-absorbing synthetic polymers on the stomatal conductance, growth and survival of transplanted Eucalyptus microtheca seedlings in the Sudan. J Appl Ecol, 1989, 26(2): 663-672.

[11]	Caravaca F, García C, Hernández MT, Roldán A. Aggregate stability changes after organic amendment and mycorrhizal inoculation in the afforestation of a semiarid site with Pinus halepensis. Appl Soil Ecol, 2002, 19: 199-208.

[12]	Childes SL, Mundy PJ. Important bird areas of Zimbabwe: a preliminary report compiled for birdlife international, 1998, Harare: Ornithological Association of Zimbabwe Press 1031

[13]	Chirino E, Vilagrosa A, Vallejo VR. Using hydrogel and clay to improve the water status of seedlings for dryland restoration. Plant Soil, 2011, 344: 99-110.

[14]	Crockford KL (1995) Yield models and tables for Pinus patula, Pinus elliottii and Pinus taeda in Zimbabwe. In: Zimbabwe bulletin of forestry research No. 12. Forest Research Centre Press, Harare, p 51

[15]	Dvorak WS, Hodge GR, Kietzka JE, Malan F, Osorio LF, Stanger TK. CAMCORE. Pinus patula. Conservation and testing of tropical and subtropical forest tree species, 2000, Raleigh: Central America & Mexico Coniferous Resources Cooperative (CAMCORE) Publishers 148 173

[16]	Fonteno WC, Bilderback TE. Impact of hydrogel on physical properties of coarse structured horticultural substrates. J Am Soc Hortic Sci, 1993, 118: 217-222.

[17]	Goosen S. Seedling survival rate increased by super absorbent polymer products. Wood SA Timber Times, 2013, 38: 12-13.

[18]	Gwaze DP, Wolliams JA, Kanowski PJ, Bridgwater FE. Interactions of genotype with site for height and stem straightness in Pinus taeda in Zimbabwe. Silvae Genet, 2001, 50: 3-4.

[19]	Hüttermann A, Zommordi M, Reise K. Addition of hydrogels to soil for prolonging the survival of Pinus halepensis seedlings subjected to drought. Soil Tillage Res, 1999, 50: 295-304.

[20]	Montesano FF, Parente A, Santamaria P, Sannino A, Serio F. Biodegradable superabsorbent hydrogel increases water retention properties of growing media and plant growth. Agric Agric Sci Procedia, 2015, 4: 451-458.

[21]	New M, Hewitson B, Stephenson DB, Tsiga A, Kruger A, Manhique A, Gomez B, Coelho CAS. Evidence of trends in daily climate extremes over southern and west Africa. J Geophys Res Atmos, 2006, 111: 1-11.

[22]	Orikiriza LJ, Agaba H, Tweheyo M, Eilu G, Kabasa JD, Huettermann A. Amending soils with hydrogels increases the biomass of nine tree species under non-water stress conditions. Clean Soil Air Water, 2009, 37: 615-620.

[23]	Oscroft DG, Little KM, Viero PWM. The effect of a soil-amended hydrogel on the establishment of Pinus elliottii x caribaea rooted cuttings on the zululand coastal sands. ICFR Bull Ser, 2000, 19: 8.

[24]	Pineiro J, Maestre FT, Bartolomé L, Valdecantos A. Ecotechnology as a tool for restoring degraded drylands: a meta-analysis of field experiments. Ecol Eng, 2013, 61: 133-144.

[25]	Sarvaš M. Effect of desiccation on the root system of Norway spruce (Picea abies [L.] Karst.) seedling and a possibility of using hydrogel STOCKOSORB^® for its protection. J For Sci, 2003, 49(11): 531-536.

[26]	Sarvaš M, Pavlenda P, Takáčová E. Effect of hydrogel application on survival and growth of pine seedlings in reclamations. J For Sci, 2007, 53: 204-209.

[27]	Save R, Pery M, Marfa O, Serrano L. The effect of a hydrophilic polymer on plant water status and survival of transplanted pine seedlings. HortTechnology, 1995, 5: 141-143.

[28]	Sloan JP. The use of rootdips on North American conifer seedlings: a review of literature. Tree Plant Note, 2004, 45: 26-31.

[29]	Sumner DM, Jacobs JM. Utility of Penman–Monteith, Priestley–Taylor, reference evapotranspiration, and pan evaporation methods to estimate pasture evapotranspiration. J Hydrology, 2005, 308: 81-104.

[30]	Taiz L, Zeiger E. Plant physiology, 2010 5 Sunderland: Sinauer Associates Inc., Publishers 778

[31]	Viero PWM, Little KM. A comparison of different planting methods, including hydrogels, and their effect on eucalypt survival and initial growth in South Africa. South Afr For J, 2006, 208: 1-5.

[32]	Viero PWM, Little KM, Oscroft DG. The effect of a soil-amended hydrogel on the establishment of a Eucalyptus grandis x E. camaldulensis clone grown on the sandy soils of Zululand. South Afr Forest J, 2000, 188: 21-28.

[33]	Viero PWM, Chiswell KEA, Theron JM. The effect of a soil-amended hydrogel on the Establishment of a Eucalyptus grandis clone on a sandy clay loam soil in Zululand during winter. South Afr For J, 2002, 193: 65-75.