Mathematical Biology & Bioinformatics | Volume 11 Issue 2 Year 2016

Priputina I.V., Frolova G.G., Bykhovets S.S., Shanin V.N., Lebedev V.G., Shestibratov K.A.

Modeling the Productivity of Forest Plantations with the Different Spacing the Trees

Mathematical Biology & Bioinformatics. 2016;11(2):245-262.

doi: 10.17537/2016.11.245.

References

Usol'tsev V.A. Fitomassa lesov Severnoi Evrazii: normativy i elementy geografii (Forest biomass of Northern Eurasia: Mensuration standards and geography elements). Yekaterinburg: Ural Branch. Russ. Acad. Sci.; 2002. 762 p. (in Russ.).
Tablitsy i modeli khoda rosta i produktivnosti nasazhdenii osnovnykh lesoobrazuiushchikh porod Severnoi Evrazii (Tables and models of growth and productivity of forests of major forest forming species of Northern Eurasia): standard and reference materials. Moscow: Rosleshoz; 2008 (in Russ.).
Landsberg J.J., Waring R.H. A generalised model of forest productivity using simplified concepts of radiation-use efficiency, carbon balance and partitioning. Forest Ecology & Management. 1997;95:209-228. doi: 10.1016/S0378-1127(97)00026-1
Repola J. Biomass equations for birch in Finland. Silva Fennica. 2008;42(4):605-624. doi: 10.14214/sf.236
Bronisz K., Strub M., Cieszewski C., Bijak S., Bronisz A., Tomusiak R., Wojtan R., Zasada M. Empirical equations for estimating aboveground biomass of Betula pendula growing on former farmland in central Poland. Silva Fennica. 2016;50(4). Article No. 1559. doi: 10.14214/sf.1559
Shutov I.V., Maslakov E.L., Markova I.A. Lesnye plantatsii: uskorennoe vyrashchivanie eli i sosny (Forest Plantations: Accelerated Cultivation of Fir and Pine). Moscow; 1984. 246 p. (in Russ.).
Lopatin E. Ustoichivoe lesopol'zovanie (Forest Management). 2016;2(46):16-24 (in Russ.).
Smirnov N.T. Izvestiia vysshikh uchebnykh zavedenii. Lesnoy Zhurnal (Bulletin of Higher Educational Institutions. Forestry Journal). 1959(4):53-59 (in Russ.).
Markova I. A. Trudy Sankt-Peterburgskogo NII lesnogo khoziaistva (Proc. of Saint Petersburg Forestry Research Institute). 2004;2(12):58-76 (in Russ.).
Usol'tsev V.A., Malenko A.A. Eko-Potentsial (Eco-Potential). 2014;3(7):34-47 (in Russ.).
Fang S., Xu X., Lu S., Tang L. Growth dynamics and biomass production in short-rotation poplar plantations: 6-year results for three clones at four spacings. Biomass & Bioenergy. 1999;17:415-425. doi: 10.1016/S0961-9534(99)00060-4
Larocque G.R. Performance and morphological response of the hybrid poplar DN-74 (Populus deltoides x nigra) under different spacings on a 4-year rotation. Annals of Forest Science. 1999;56:275-287. doi: 10.1051/forest:19990402
Gazizullin A.Kh. Current state of forest biotechnology in the world and in Russia. Vestnik of Kazan State Agrarian University. 2012;4(26):94-98 (in Russ.).
Almeida A.C., Landsberg J.J., Sands P.J., Ambrogi M.S., Fonseca S., Barddal S.M., Bertolucci F.L. Needs and opportunities for using a process-based productivity model as a practical tool in Eucalyptus plantations. Forest Ecology & Management. 2004;193(1-2):167-177. doi: 10.1016/j.foreco.2004.01.044
Shestibratov K., Lebedev V., Podrezov A., Salmova M. Transgenic aspen and birch trees for Russian plantation forests. BMC Proceedings. 2011;5(7):124. doi: 10.1186/1753-6561-5-S7-P124
Romanov E.M., Nureeva T.V., Eremin N;The role of planted forests in improving the productive capacity and ecological potential of Scots pine boreal forests in the Middle Volga Region. New Zealand Journal of Forestry Science. 2016;(46):1-11. Article No. 10.
Karev G.P., Skomorovsky Ju. I. Modelling of dynamics of single breed tree stands. Siberian Journal of Ecology. 1999;4:403-417 (in Russ.).
Shchedrina T.L. Suktsessionnaia dinamika lesov boreal'noi zony (Successional Dynamics of Boreal Zone Forests): Abstract of the Thesis Ph.D. Novosibirsk; 2000 (in Russ.).
Chumachenko S.I. Imitatsionnoe modelirovanie mnogovidovykh raznovozrastnykh lesnykh nasazhdenii (Simulation modeling of multi-species mixed-age forest plantations): Doctorate Degree in Biological Sciences. Moscow; 2006. 287 p. (in Russ.).
Kolobov A.N., Frisman E.Y. Simulation of the competition for light in forest stands of the same age. Biology Bulletin. 2013;40(4):394-403. doi: 10.1134/S1062359013040067
Galitskii V.V. Collective self-suppression in a homogeneous plant community and oscillatory changes in the biomass of its members. Doklady Biological Sciences. 1979;46(1-6):891-893.
Galitskii V.V., Komarov A.S. In: Modelirovanie pochvennykh protsessov i avtomatizatsiia ikh issledovanii (Modeling of Soil Processes and Automation of their Research). Moscow; 1976. P. 91-106 (in Russ.).
Sennov S.N. The results of experimental study of forest stand competition. In: Izvestia Sankt-Peterburgskoj lesotehniceskoj akademii (Bulletin of the St.Petersburg Forest Technical Academy). Saint Petersburg; 1993. P. 160-172 (in Russ.).
Usol'tsev V.A., Semyshev M.M. Production characteristics with taking into account tree competitiveness of artificial and natural pine forests: comparative analysis. Bulletin of Volga State University of Technology. 2010;2:5-13 (in Russ.).
Komarov A.S., Chertov O.G., Zudin S.L., Nadporozhskaya M.A., Mikhailov A.V., Bykhovets S.S., Zudina E.V., Zoubkova E.V. EFIMOD 2 - a model of growth and cycling of elements in boreal forest ecosystems. Ecological Modelling. 2003;70:373-392. doi: 10.1016/S0304-3800(03)00240-0
Komarov A.S., Chertov O.G., Bykhovets S.S., Priputina I.V., Shanin V.N., Vidjagina E.O., Lebedev V.G., Shestibratov K.A. Effects of the Aspen Short-Rotation Plantation on the C and N Biological Cycles in Boreal Forests: The Model Experiment. Mathematical Biology and Bioinformatics. 2015;10(2):398-415 (in Russ.). doi: 10.17537/2015.10.398
Priputina I.V., Frolova G.G., Shanin V.N. Substantiation of optimum planting schemes for forest plantations: computer experiment. Computer Research and Modeling. 2016;8(2):333-343 (in Russ.)
Pisarenko A.I., Merzlenko M.D. Sozdanie iskusstvennykh lesov (Artificial Forest Creation). Moscow: Agropromizdat; 1990 (in Russ.).
Chertov O.G., Komarov A.S., Nadporozhskaya M.A., Bykhovets S.S., Zudin S.L. ROMUL – a model of forest soil organic matter dynamics as a substantial tool for forest ecosystem modeling. Ecological Modelling. 2001;138:289-308. doi: 10.1016/S0304-3800(00)00409-9
Bykhovets S.S., Komarov A.S. A simple statistical model of soil climate with a monthly step. Eurasian Soil Science. 2002;35(4):392-400.
Komarov A.S., Chertov O.G. Ekologiia i pochvy (Ecology and Soils. Selected Lectures of the 10th All-Russia School). Pushchino; 2001. P. 76-84 (in Russ.).
Modelirovanie dinamiki organicheskogo veshchestva v lesnykh ekosistemakh (Modeling Organic Matter Dynamics in Forest Ecosystems). Ed. V.N. Kudeyarov. Moscow; 2007. 380 p. (in Russ.).
Shanin V.N., Komarov A.S., Bykhovets S.S. Simulation modelling for sustainable forest management: a case-study. Procedia Environmental Sciences. 2012;13:535-549. doi: 10.1016/j.proenv.2012.01.044
Komarov A.S., Khoraskina Yu.S., Bykhovets S.S., Bezrukova M.G., Chertov O.G. Modeling of the Soil Organic Matter Dynamics and the Soil Nutrients in Mineral Soil and Forest Floor. Mathematical Biology and Bioinformatics. 2012;7(1):162-176 (in Russ.). doi: 10.17537/2012.7.162
Tsel'niker Iu.L. Fiziologicheskie osnovy tenevynoslivosti derev'ev (Physiological Basis of Shade Tolerant Woody Plants). Moscow: Nauka; 1978. 215 p. (in Russ.).
Alekseev V.A. Svetovoi rezhim lesa (Forest Light Regime). Leningrad; 1975. 228 p. (in Russ.).
Tomppo E. Models and methods for analyzing spatial patterns of trees. Commun. Inst. Forest. Fenn. 1986;138:1-65.
Pukkala T., Kolström T. Competition indices and the prediction of radial growth in Scots pine. Silva Fennica. 1987;21(1):55-76. doi: 10.14214/sf.a15463
Pukkala T. Methods to describe the competition process in a tree stand. Scandinavian Journal of Forest Researches. 1989;4(1):187-202. doi: 10.1080/02827588909382557
Ford E.D., Sorrensen K.A. Theory and models of inter-plant competition as a spatial process. In: Individual-based models and approaches in ecology. N.Y., L.: Chapman and Hall; 1992. P. 363-407. doi: 10.1007/978-1-4757-0869-1_17
Marklund L.G. Biomassafunktioner for tall, gran och bjork i Sverige (Biomass functions for pine, spruce and birch in Sweden). Department of Forest Survey, Swedish University of Agricultural Sciences, Report 45. 1988. 73 p. (in Swedish with English summary).
Harper J.L. Population biology of plants. N.Y.: Acad. Press; 1977.
Chertov O.G., Komarov A.S, Tsiplyanovsky A.M. A combined simulation model of Scots pine, Norway spruce and Silver birch ecosystems in European boreal zone. Forest Ecology & Management. 1999;116:189-206. doi: 10.1016/S0378-1127(98)00456-3
Fern A. Birch production and utilization for energy. Biomass and Bioenergy. 1993;4(6):391-404. doi: 10.1016/0961-9534(93)90061-8
Uri V., Lõhmus K., Ostonen I., Tullus H., Vildo M. Biomass production, foliar and root characteristics and nutrient accumulation in young silver birch (Betula pendula Roth) stand growing and abandoned agricultural land. European Journal of Forest Research. 2007;126:495-506. doi: 10.1007/s10342-007-0171-9
Uri V., Varik M., Aossar J., Kanal A., Kukumägi M., Lõhmus K. Biomass production and carbon sequestration in a fertile silver birch (Betula pendula Roth) forest chronosequence. Forest Ecology and Management. 2012;267:117-126. doi: 10.1016/j.foreco.2011.11.033
Koski V., Rousi M. A review of the promises and constraints of breeding silver birch (Betula pendula Roth) in Finland. Forestry. 2005;78(2):187-198. doi: 10.1093/forestry/cpi017
Denisov S. A., Glushkova Iu. P., Tueva L. E. Vestnik MarGTU (Bulletin of Volga State University of Technology). 2008;2:28-30 (in Russ.).
Bulygina O.N., Razuvaev V.N., Korshunova N.N., Shvets N.V. Massiv dannykh mesiachnykh summ osadkov na stantsiiakh Rossii (Obninsk, All-Russian Research Institute of Hydrometeorological Information). http://meteo.ru/data/158-total-precipitation#opisanie-massiva-dannykh (accessed 02 November 2015).
Bulygina O.N., Razuvaev V.N., Trofimenko L.T., Shvets N.V. Massiv dannykh srednemesiachnoi temperatury vozdukha na stantsiiakh Rossii (Obninsk, All-Russian Research Institute of Hydrometeorological Information). http://meteo.ru/data/156-temperature#opisanie-massiva-dannykh (accessed 02 November 2015).
Sherstiukov A.B. Massiv sutochnykh dannykh o temperature pochvy na glubinakh do 320 sm po meteorologicheskim stantsiiam Rossiiskoi Federatsii (Obninsk, All-Russian Research Institute of Hydrometeorological Information). http://meteo.ru/data/164-soil-temperature#opisanie-massiva-dannykh (accessed 02 November 2015).
Edinyi gosudarstvennyi reestr pochvennykh resursov Rossii (Unified State Register of Soil Resources of Russia). http://atlas.mcx.ru/materials/egrpr/content/soils/soil102.html (accessed 10 November 2015).
Agrokhimicheskaia kharakteristika pochv SSSR. Raiony Tsentral'noi chernozemnoi polosy i Moldavskoi SSR (Agrochemical Characteristics of the Soils of the USSR. Areas of the Central Chernozem Zones and Moldavia Republic). Eds. A.V. Sokolov, E.I. Shkonde. Moscow; 1963. 264 p. (in Russ.).
Spravochnik agronoma po sel'skokhoziaistvennoi meteorologii (Reference Book for Agronomist on Agricultural Meteorology). Ed. I.G. Gringof. Leningrad; 1986. 528 p. (in Russ.).
Natsional'nyi Atlas Rossii. V. 2. Priroda i ekologiia (The National Atlas of Russia. V.2. The Nature. Ecology). Moscow; 2007 (in Russ.).
Liesebach M., von Wuechlisch G., Muhs H.J. Aspen for short-rotation coppice plantations on agricultural sites in Germany: Effects of spacing and rotation time on growth and biomass production of aspen progenies. Forest Ecology & Management. 1999;121:25-39. doi: 10.1016/S0378-1127(98)00554-4
Kapel'kina L.P. In: Fundamental'nye i prikladnye voprosy lesnogo pochvovedeniia (Fundamental and Applied Aspects of Forest Soil Science): Proceedings of the VI All-Russian Scientific Conference. Syktyvkar; 2015. P. 94-95 (in Russ.).
Sobachkin D.S., Ben'kova V.E., Sobachkin R.S., Buzykin A.I. Lesovedenie (Russian Journal of Forest Science). 2009;2:73-79 (in Russ.).