References
- Augspurger CK, Bartlett EA. 2003. Differences in leaf phenology between juvenile and adult trees in a temperate deciduous forest. Tree Physiol. 23:517–525.
- Duffková R. 2006. Difference in canopy and air temperature as an indicator of grassland water stress. Soil & Water Res. 2006:127–138.
- Fujimoto S. 2007. Analysis of prediction methods for budburst days based on the phenological observation in 29 broad-leaved tree species for 10 years. J Jpn For Soc. 89:253–261. Japanese with English summary.
- Hokyo N. 1972. Studies on the life history and the population dynamics of the green rice leafhopper, Nephotettix cincticeps Uhler. Bull Kyushu Agric Exp Stn. 16:283–382. Japanese with English summary.
- IAWA Committee. 1989.IAWA list of microscopic features for hardwood identification. Wheeler EA, Baas P, Gasson PE, editors. IAWA Bulletin n.s: Vol. 10. Leiden (Netherlarnds): National Herbarium of the Netherlands; p. 219–312.
- JAFTA (Japan Forestry Technical Association). 1964. Illustrated important forest trees of Japan. Tokyo:Chikyu Shuppan. Japanese.
- Kai K, Kainuma M, Murakoshi M, Omasa K. 1993. Potential effects on the phenological observation of plants by global warming in Japan. J Agr Met. 48:771–774.
- Kamata N, Kimura N, Iguchi K, Fukuoka S, Ogawa H, Kasahara H, Shibano S, Takahashi Y, Inukai M, Sasaki C, et al. 2019. Long-term phenology data on woody plants at The University of Tokyo Hokkaido Forest from 1930 to 2010. Misc Info Univ Tokyo For. 61:45–63. Japanese with English summary.
- Kikuzawa K. 1995. Leaf phenology as an optimal strategy for carbon gain in plants. Can J Bot. 73:158–163.
- Kikuzawa K. 1999. Global change and phenology of woody plants. Kawano S, Imura O, editors. Environmental changes and populations. Tokyo: Kaiyusha; 36–52. Japanese.
- Kimura N, Kisanuki H, Kurahashi A. 1995. Some phenological characters on 25 broad-leaved deciduous tree species in Hokkaido. Annual fluctuations and effect of monthly mean temperature. Proc Ann Mtg Jpn For Soc. 106:367–370. Japanese.
- Kira T. 1945. A new classification of climate in eastern Asia as the basis for agricultural geography. Kyoto: Horticultural Institute, Kyoto Imperial University. Japanese.
- Kira T. 1949. Forest zones in Japan. Tokyo: Japan Forestry Technology Association. Japanese.
- Kira T. 1977. A climatological interpretation of Japanese vegetation zones. In: Miyawaki A, Tüxen R, Okuda S, editors. Vegetation science and environmental protection. Tokyo: Maruzen; p. 21–30.
- Koike T, Sakagami Y, Fujimura Y. 1984. Leaf expansion rate and leaf survival on different crown position of three birch species in Hokkaido. Proc Ann Mtg Jpn For Soc. 95:371–372. Japanese.
- Koike T, Sakagami Y, Fujimura Y. 1986. A method for measuring photosynthesis with detached parts of deciduous broad-leaved trees in Hokkaido. J Jpn For Soc. 68:425–428.
- Kozlowski TT, Pallardy SG. 1997. Growth control in woody plants. New York (NY): Academic Press.
- Kramer PJ, Kozlowski TT. 1979. Physiology of woody plants. New York (NY): Academic Press.
- Lyr H, Polster H, Fiedler HJ. 1967. Gehölzphysiologie [Physiology of woody plants]. Jena (German): Sustav Fischer Verlag.
- Menzel A. 2002. Phenology: its importance to the global change community. Clim Change. 54:379–385.
- Nam Y, Koh S-H, Won D-S, Kim J-K, Choi WI. 2013. An empirical predictive model for the flight period of Platypus koryoensis (Coleoptera: platypodinae). Appl Ent Zool. 48:515–524.
- Osada N, Murase K, Tsuji K, Sawada H, Nunokawa K, Tsukahara M, Hiura T. 2018. Genetic differentiation in the timing of budburst in Fagus crenata in relation to temperature and photoperiod. Int J Biometeorol. 62:1763–1776.
- Richardson AD, O’Keefe J. 2009. Phenological differences between understory and overstory: A case study using the long-term Harvard forests. In: Noormets A, editor. Phenology of ecosystem processes: applications in global change research. New York (NY): Springer; p. 87–117.
- Sawada H, Kabaya H, Omura K, Chishima T. 1999. The fluctuations of some characters of six trees of Quercus mongolica var. grosseserrata in the Tokyo University Forest in Chichibu. Proc Ann Mtg Kanto Br Jpn For Soc. 50:79–80. Japanese.
- Seiwa K. 1999a. Changes in leaf phenology are dependent on tree height in Acer mono, a deciduous broad-leaved tree. Ann Bot. 83:355–361.
- Seiwa K. 1999b. Ontogenetic changes in leaf phenology of Ulmus davidiana var. japonica, a deciduous broad-leaved tree. Tree Physiol. 19:793–797.
- Stamp NE. 1993. A temperate region view of the interaction of temperature, food quality, and predators on caterpillar foraging. In: Stamp NE, Casey TM, editors. Caterpillars: ecological and evolutionary constraints on foraging. New York (NY): Chapman and Hall; p. 478–508.
- Tanaka N, Kamata N, Shibano H, Owari T, Ohkawa A, Igarashi Y, Arakida K. 2013. Estimation of long-term data sets of annual mean temperature in ecohydrology research institute, the University of Tokyo Hokkaido Forest, and the University of Tokyo Chichibu Forest. Bull Univ Tokyo For. 128:1–19. Japanese.
- Tsugane R. 1975. The life cycle of Amphipyra livida corvina Matschulsky (Lepidoptera: noctuidae), with special reference to the termination of aestivation in the adult stage. Jap J Appl Ent Zool. 19:169–175. Japanese with English summary.
- Tyree MT, Zimmermann MH. 2002. Xylem structure and the ascent of sap. Berlin Heidelberg: Springer.
- Umeya K, Yamada H. 1973. Threshold temperature and thermal constants for development of the diamond–back moth, Plutella xylostella L., with reference to their local differences. Jap J Appl Ent Zool. 17:19–24. Japanese with English summary.
- Valentine HT. 1983. Budbreak and leaf growth functions for modelling herbivory in some gypsy moth hosts. For Sci. 29:607–617.
- Yamamura K, Kiritani K. 1998. A simple method to estimate the potential increase in the number of generations under global warming in temperate zones. Appl Ent Zool. 33:289–298.