prilagođeno pretraživanje po punom tekstu

ŠUMARSKI LIST 7-8/2022 str. 43     <-- 43 -->        PDF

size variations in natural populations at different elevations. Alp Bot, 129(2):163-174.
Musil, I., J., Hamerník, 2007: Jehličnaté dřeviny. Praha, Academia: 352.
Naudiyal N., J., Wang, W., Ning, N.P., Gaire, S., Peili, W., Yanqiang, S., Ning, 2021: Potential distribution of Abies, Picea, and Juniperus species in the subalpine forest of Minjiang headwater region under current and future climate scenarios and its implications on ecosystem services supply. Ecol Indic, 121:07-131.
Niinemets, U., D.S., Ellsworth, A., Lukjanova, M., Tobias, 2001: Site fertility and the morphological and photosynthetic acclimation of Pinus sylvestris needles to light. Tree Physiol, 21: 1231-1244.
Nunes, A., G., Oliveira, T., Mexia, A., Valdecantos, C., Zucca, E.A., Costantini, C., Branquinho, 2016: Ecological restoration across the Mediterranean Basin as viewed by practitioners. Sci Total Environ, 566, 722-732.
Olascoaga, B., E., Juurola, P., Pinho, P., Lukeš, L., Halonen, E., Nikinmaa, J., Bäck, A., Porcar-Castell, 2014: Seasonal variation in the reflectance of photosynthetically active radiation from epicuticular waxes of Scots pine (Pinus sylvestris) needles. Boreal Environ Res, 19: 132 (Supplement B).
Pandey, S., 2021: Climatic influence on tree wood anatomy: a review. J Wood Sci, 67(1):1-7.
Paule, L., D., Gömöry, R., Longauer, D., Krajmerová, 2001: Patterns of genetic diversity distribution in three main Central European montane tree species: Picea abies Karst., Abies alba Mill. and Fagus sylvatica L. Lesn. Čas. For Journal, 47(2): 152-163.
Pawlaczyk, E.M., J., Grzebyta, M.A., Bobowicz, A.F. Korczyk, 2005: Individual differentiation of Abies alba Mill. population from the Tisovik reserve. Variability expressed in morphology and anatomy of needles. Acta Biol Crac Ser Bot, 47(2), 137–144
Pensa M., T., Aalto, R., Jalkanen, 2004: Variation in needle-trace diameter in respect of needle morphology in five conifer species. Trees Struct Funct, 18:307–311.
Poljak, I., J., Vukelić, A., Vidaković, M., Vuković, M., Idžojtić, 2020: Variability of the populations of Scots pine (Pinus sylvestris L.) in the northwestern part of Mala Kapela according to the morphological characteristics of the needles and cones, Sumar List, 144(11-12): 539-549.
Popnikola, N. 1974: Varijabilnost četina jele (Abies alba Mill.) u prirodnim populacijama SR Makedonije. Šumarstvo 27 (5-6) 3-14.
Postolache, D., C., Leonarduzzi, A., Piotti, I., Spanu, A., Roig, B., Fady, A., Roschanski, S., Liepelt, G.G., Vendramin, 2013: Transcriptome versus genomic microsatellite markers: highly informative multiplexes for genotyping Abies alba Mill. and congeneric species. Plant Mol Biol Report, 32: 750-760. doi: 10.1007/s11105-013-0688-7.
Radu, Gh.R., Al.L., Curtu, Gh., Spârchez, N., Şofletea, 2014: Genetic diversity of Norway spruce [Picea abies (L.) Karst.] in Romanian Carpathians. Ann For Res, 57(1): 19-29. doi: 10.15287/afr.2014.178.
Robakowski, P., S., Samardakiewicz, D., Kierzkowski, 2004: Variation in structure of needles of silver fir (Abies alba Mill.) saplings growing under the canopies of diverse tree species. Pol J Ecol, 52: 563-568.
Sánchez-Velásquez, L. R., M., del Rosario Pineda-López, S.P., Ibarra-Zavaleta, Y., López-Serrano, 2021: Fir forest demography using matrix projections: Anomaly precipitation due to climatic change decrease population viability. For Ecol Manage, 482, 118845.
Schoettle A.W., S.G., Rochelle, 2000: Morphological variation of Pinus flexilis (Pinaceae), a birddispersed pine, across a range of elevations. Am J Bot, 87(12): 1797-1806.
Thompson, I., B., Mackey, S., McNulty, A., Mosseler, 2009: Forest resilience, biodiversity, and climate change. A Synthesis of the Biodiversity/Resilience/Stability in Forest Ecosystems. Secretariat of the Convention on Biological Diversity, Montreal, Technical Deries, 43, 67 p.
Tiwari, S. P., P., Kumar, D., Yadav, D.K., Chauhan, 2013: Comparative morphological, epidermal, and anatomical studies of Pinus roxburghii needles at different altitudes in the North-West Indian Himalayas. Turk J Botany, 37(1), 65-73.
Turunen M., W., Heller, S., Stich, H., Sandermann, M.L., Sutinen, 1999: Effects of UV exclusion on phenolics compounds of young Scots pine seedlings in the subarctic. Environ Pollut, 106: 225-234. doi: 10.1016/s0269-7491(99)00070-6.
Urbaniak, L., L., Karliński, R., Popielarz, 2003: Variation of morphological needle characters of Scots pine (Pinus sylvestris L.) populations in different habitats. Acta Soc Bot Pol, 72: 37-44. doi: 10.5586/asbp.2003.005.
Wang J., J., Ma, F., OuYang, J., Wang, L., Song, L., Kong, H., Zhang, 2020: Instrinsic relationship among needle morphology, anatomy, gas exchanges and tree growth across 17 Picea species. New For, 1-27. doi: 10.1007/s11056-020-09808-z.
Wang, T., A., Hamann, D.L., Spittlehouse, T.Q., Murdock, 2012: ClimateWNA-high-resolution spatial climate data for western North America. J Appl Meteorol Climatol, 51(1), 16-29.
Wolf, H., 2003: EUFORGEN Technical Guidelines for genetic conservation and use for silver fir (Abies alba). International Plant Genetic Resources Institute, Rome, Italy. 6 p.
Xing F., J.F., Mao, J., Meng, J., Dai, W., Zhao, H., Liu, Y., Li, 2014: Needle morphological evidence of the homoploid hybrid origin of Pinus densata based on analysis of artificial hybrids and the putative parents, Pinus tabuliformis and Pinus yunnanensis. Ecol Evol, 4(10), 1890-1902.doi: 10.1002/ece3.1062 .
Zhang M., J.X., Meng, Z.J., Zhang, S.L., Zhu, Y., Li, 2017: Genetic Analysis of Needle Morphological and Anatomical Traits among Nature Populations of Pinus tabuliformis. J Plant Stud, 6(1). p62. doi:10.5539/jps.
Zhu, J., A., Thimonier, S., Etzold, K., Meusburger, P., Waldner, M., Schmitt, P., Schleppi, M., Schaub, J.J., Thormann, M.M., Lehmann, 2022: Variations in leaf morphological traits of European beech and Norway spruce over two decades in Switzerland. Front For Glob Change, 4(207):1-17.