Effects of gap canopy size on seed germination of Acer velutinum and Diospyrus lotus as pioneer species

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Volume 5, Issue 11 (3-2018)

PEC 2018, 5(11): 205-216

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Effects of gap canopy size on seed germination of Acer velutinum and Diospyrus lotus as pioneer species

Abstract: (3736 Views)

Establishment of natural regeneration inside gap canopy is one of the challenges for forest managers so collecting of information about how the gap canopy could effects on quantitative and qualitative characteristic of seed germination of trees especially pioneer species is so valuable. To achieve this goal, 24 canopy gaps were identified from a mixed Fagetum stand at Hajikola-Tirankli forestry plan from Tajan River watershed. In the following, the canopy gaps were classified to three difference size classes such as smaller than 150 (small), 150-350 (moderate) and 350-500 m² (large) and the seeds of the Acer velutinum and Diospyrus lotus as pioneer species were collected from inside and outside of the canopy gaps and seed germination test were done on the collected seed. Seed germinant percent and germination speed were calculated and then statistically analyzed. The results about Acer velutinum showed that although seed germination percent of the species wasn’t different between inside and outside of the canopy gaps, seed germination speed of the pioneer species was higher in collected seeds from inside than those collected from outside of the canopy gaps. Seed germination percent of Diospyrus lotus collecting from inside of canopy gaps with 150-350 and 350-500 m² sizes were higher around 20% than those collected from next control stands. Moreover, the highest seed germination speed was observed in collected seeds from large canopy gaps. Overall, the positive effects of canopy gaps with 150-500 m² area in keeping seed germination conditions of the both species was proven by the current research.

Keywords: natural regeneration, germination, seed, pioneer species, canopy gaps

Full-Text [PDF 768 kb] (2758 Downloads)

Type of Study: Research | Subject: Special
Received: 2017/04/18 | Accepted: 2017/08/1 | Published: 2018/05/25

References

1. Abrari Vajari, K., Jalilvand, H., Pourmajidian, M. R., Espahbodi, K., and Moshki, A. (2012). Effect of canopy gap size and ecological factors on species diversity and beech seedlings in managed beech stands in Hyrcanian forests. Journal of Forestry Research, 23(2): 7-14.

2. Baskin, C. C. and J. M. Baskin. 2001. Seeds: Ecology, biogeography, and evolution of dormancy and germination. Academic Press, San Diego, CA, USA.

3. Bradford, K. J. 1990. A water relation analysis of seed germination rates. Plant Physiol, 94: 840-849.

4. Bradford, K. J. 2002. Applications of hydrothermal time to quantifying and modeling seed germination and dormancy. Weed Science, 50: 248–260.

5. Brokaw, N.V.L. & Scheiner, S.M., 1989. Species composition in gaps and structure of a tropical forest. Ecology, 70: 538-541.

6. Clinton, B.D. 2003. Light, temperature, and soil moisture responses to elevation, evergreen understory, and small canopy gaps in the southern Appalachians. Forest Ecology and Management 186: 243–255.

7. Guerke, W. R., Gutormson, T., Meyer, D., McDonald, M., Mesa, D., Robinson, J. C. and Tekrony, D. 2004. Application of hydrotime analysis in seed testing. Seed Technology, 26 (1): 75-85

8. Larsen, S. U., Bailly, C., Côme, D. and Corbineau, F. 2004. Use of the hydrothermal time model to analyse interacting effects of water and temperature on germination of three grass species. Seed Science Research, 14, 35–50.

9. Mihok, B., L.Gálhidy, K. Kenderes, and T. Standovár, 2007. Gap regeneration patterns in a semi-natural beech forest stand in Hungary, Acta Silvatica Lignaria Hungarica, 3: 31–45.

10. Raich, J. W., 1990. Effects of canopy openings on tree seed germination in a Malaysian dipterocarp forest. Journal of tropical ecology. 6: 203-217.

11. Ren, J.Y., Kadir, A. and Yue, M., 2015. The role of tree‐fall gaps in the natural regeneration of birch forests in the Taibai Mountains. Applied Vegetation Science, 18(1), pp.64-74.

12. Santiago, J. M. & Amanda, D. R. 2005. Dead trees resources for forest wildlife, extension fact sheet. Ohio State University Express.

13. Scharenbroch, B.C., and Bockheim, J.G. 2007. Impacts of forest gaps on soil properties and processes in old growth northern hardwood-hemlock forests. Plant Soil. 294: 219-233.

14. Thygerson, T., Harris, J. M., Smith, B. N., Hansen, L. D., Pendleton, R. L. and Booth, D. T. 2002. Metabolic response to temperature for six populations of winterfat (Eurotia lanata). Thermochimica Acta, 394: 211-217

15. Woods, K.D., 2000. Dynamics in late-successional hemlock-hardwood forests over three decades. Ecology, 81: 110-126.

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Effects of gap canopy size on seed germination of Acer velutinum and Diospyrus lotus as pioneer species. PEC 2018; 5 (11) :205-216
URL: http://pec.gonbad.ac.ir/article-1-313-en.html

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