芭樂樹幼枝形成層活動之季節性

Tan Chou; 周淡

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DC 欄位	值	語言
dc.contributor.author	Tan Chou	en
dc.contributor.author	周淡	zh_TW
dc.date.accessioned	2021-07-01T08:13:25Z	-
dc.date.available	2021-07-01T08:13:25Z	-
dc.date.issued	1972
dc.identifier.citation	Bailey, I.W. 1923. The cambium and its derivative tissues. Ⅳ. The increase in girth of the cambium. Amer. J. Bot. 10 499-509. Catesson, A. 1964. Origine, fonctionnement et variations cytologiques saisonnieres du cambium, de l'Acer pseudoplatanus L. (Aceracees). Annales des Sciences Naturelles, Botanique, Paris, 12e serie, 5:229-498. (cited by Fahn, 1967) Chowdhury, K.A. 1969. Cambial activity in temperate and tropical trees. ?. Int. Bot. Congr. Seattle, Abstr.:32. (cited by Paliwal & Prasad, 1970) Cockerham, G. 1930. Some observations on cambial activity and seasonal starch content in sycamore (Acer pseudoplatanus). Proc. Leeds. Phil. Lit. Soc. 2:64-80. (cited by Esau, 1965) Cutter, E.G. 1969. Plant Anatomy. Experiment and Interpretation. Part Ⅰ. Cells and Tissues. Edward Arnold (Publishers) Ltd., London. Derr, W.F. & R.F. Evert. 1967. The cambium and seasonal development of the phloem in Robinia pseudoacacia. Amer. J. Bot 54:147-153. Digby, J. & P.F. Wareing. 1966a. The effect of applied growth hormones on cambial division and the differentiation of the cambial derivatives. Ann. Bot. N.S. 30 539-548. ________, 1966b. The relationship between endogenous hormone levels in the plant and seasonal aspects of cambial activity. Ann. Bot. N.S. 30: 07-622. Esau, K. 1965. Plant Anatomy. 2nd. ed. John Wiley & Sons, Inc., New York. London. Sydney. Evert, R.F. 1961. Some aspects of cambial development in Pyrus communis. Amer. J. Bot. 48:479-488. _____, 1963. The cambium and seasonal development of phloem in Pyrus malus. Amer. J. Bot. 50:149-159. _____, & T.T. Kozlowski. 1967. Effect of isolation of bark on cambial activity and development of xylen and phloem in trembling aspen. Amer. Boy. 54:1045-1054. Fahn, a. 1958a. Xylem structure and annual rhythm of development in trees and shrubs of the desert. I. Tamarix aphylla, T. jordanis var. negevensis, T. gallica var. marismortui. Trop. Woods 109:81-94. (cited by Fahn, 1967) _______, 1958b. Xylem structure and annual rhythm of development in trees and shrubs of the desert. Ⅱ. Acacia tortilis and A. raddiana. Bull. Res. Counc. Israel 7D:23-28. (cited by Fahn, 1967) _______, 1959. Xylem structure and annual rhythm of development in trees and shrubs of the desert. Ⅲ. Eucalyptus camaldulensis and Acacia cyanophylla. Bull. Res. Counc. Israel 7D:122-129. (cited by Fahn, 1967) _______, 1967. Plant Anatomy. Pergamon Press. Oxford. London. Edingurgh. New York. Roronto. Sydney. Paris. Braunschweig. Gregory, R.A. 1971. Cambial activity in Alaskan white spruce. Amer. J. Bot. 58:160-171. Ladefoged, K. 1952. The periodicity of wood formation. Kgl. Dansk. Vidensk. Selsk. Biol. Scr. 7:1-98. (cited by Esau, 1965) Larson, P.R. 1962. The indirect effect of photoperiod on trach?id diameter in Pinus resinosa. Amer. J. Bot. 9: 132-137. Liu, Y, C. 1964. Dendrology. 3rd. ed. Metcalfe, C.R. & L. Chalk. 1950. Anatomy of the dicotyledons. Vol. I. Oxford at the clearendon press. Paliwal, G.S. & N.V.S.R.K. Prasad. 1970. Seasonal activity of cambium in some tropical trees. I. Dalbergia sissoo. Phytomorph. 20: 333-339. Snow. R. 1933. The nature of the cambial stimulus. New Phytol. 34:288-296. _____, 1935. Activation of cambial growth by pure hormones. New Phytol. 34: 347-359. Srivastava. L.M. 1966. On the fine structure of the cambium of Fraxinus americana L. Jour. Cell Biol. 31: 79-93. Waisel, Y. & A. Fahn. 1965. The effects of environment of wood formation and cambial activity in Robinia pseudoacacia L. New Phytol. 64:436-442. _______, N. Liphschitz, & T. Arzee. 1967. Phellogen activity in Robinia pseudoacacia, L. New Phytol. 66: 331-335. Wareing, P.F. 1951. Growth studies in woody species. Ⅳ. The initiation of cambial activity in ring-porous species. Physiol. Plant. 4:546-562. _______, & D.L. Robert. 1956. Photoperiodic control of cambial activity in Robinia pseudoacacia L. New Phytol. 55:356-366.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/75479	-
dc.description.abstract	1．芭樂樹周皮在二年生的幼枝裹已取代表層組織的功能，木栓形成層向外分裂產生的木栓組織只含有一種形態的木栓細胞，木栓形成層的?命極長，至少在五年之中未失去其活動力，栓皮組織不如木栓組織發達，有些細胞內含有結晶體。 2．皮層由等徑的薄壁細胞和不規則形的石細胞構成。薄壁細胞含有葉綠體，或?多面體結晶所佔據，細胞常連接成串。石細胞具極厚之次生細胞壁，其上有無緣孔，射線延長線上的擴張組織隨形成層的發育逐漸發達，七月至九月最?顯著。 3．管束形成層之活動期極長，自二月初至十一月，六月初?其活動之最高潮時期，其活動速率受氣溫影響十分顯著，溫度逐漸上升時，形成層活動力增強，28℃左右時活動最旺盛，超過此溫度後，並不能再促進其活力，反而有減慢的現象。形成層帶細胞的層數隨其活動速率的快慢有所增減。 4．後生木質部?典型的散孔材，導管細胞口徑?20至50μ之間，第一年的木材裹就有?充細胞出現；射線密集，單層和多層（兩層居多）射線俱存；?向薄壁細胞?離管型分佈，自散狀至帶狀。 5．韌皮部組織不若木質部發達，除節管細胞及伴細胞外，韌皮薄壁細胞因含有多面形結晶十分顯眼。不規則形的石細胞單獨存在或成帶分佈，細胞形態與皮層內者無異。 6．髓部亦由薄壁細胞及不規則形之石細胞所組成，此處之薄壁細胞內無葉綠體，而?多面體或晶簇狀結晶所充斥，石細胞與皮層，韌皮部內者相同。 7．芭樂樹的葉芽於四月初大量萌發，七月以後新葉生長逐漸停止；開花期則於五月和十月時較?集中，其餘時期亦斷續有開花現象。形成層之活動期開始於葉芽萌發之前，第一次花期正?形成層活動旺盛之時，第二次的花期則在形成層活動的末期。	zh_TW
dc.description.abstract	1. The primary epidermal tissue was replaced by periderm when the young branch of guava tree (Psidium guajava Linn.) bore two to three growth rings. The phellogen, cork cambium, produced less phelloderm cells than the phellem which was composed of only one type of cells. The second layer of new cork cambium has not been identified in all the branches which bore one to five growth rings during the period of this experiment. Some of the cells in phelloderm contain prismatic crystals. 2. Cortex is made up of two kinds of cells: isodiametric parenchyma and irregular stone cells. Chloroplasts are constantly present in the parenchyma. Occasionally some parenchyma cells are occupied by prismatic crystals and they are always arranged in a string. The expansion tissue in the cortex developed as the vascular cambium began to activate and they were in the grand period of active stage during July to September. 3. The period of cambial activity was very long. It began in early February, ended in November. The most conspicuous cambial activity was seen in early June. When the temperature gradually rised the cambial activity increased. But it slowed down as the temperature was over 28℃. 4. A typical diffuse-porous wood is showed in the secondary xylem. Tyloses are observed even in the wood formed in the first year. Both uniseriate and multiseriate rays are close distributed. Apotracheal axial parenchyma appear in either diffuse or banded form in three to five rows. 5. Pith is also composed of parenchyma and brachysclereids (irregular stone cells). Chloroplasts are not found in the parenchyma cells but the various shapes of crystals: prismatic, druses and irregular forms are abundant in them. 6. At the beginning of April the leaf buds sprouted in a large amount. Then, the new leaves continued to grow till late July. Two main flowering periods were figured as in May and October. The reactivation of the cambium began prior to the sprouting of the leaf buds and the first flowering period was corresponded with the grand active stage of the cambium.	en
dc.description.provenance	Made available in DSpace on 2021-07-01T08:13:25Z (GMT). No. of bitstreams: 0 Previous issue date: 1972	en
dc.description.tableofcontents	一、中文摘要……………………………………………………1 二、英文摘要……………………………………………………3 三、緒論……………………………………………………5 四、材料與方法……………………………………………………12 五、結果 (一) 周皮……………………………………………………16 (1) 木栓層……………………………………………………16 (2) 栓皮……………………………………………………21 (二) 皮層……………………………………………………22 (三) 形成層及其衍生組織……………………………………………………27 (1) 管束形成層……………………………………………………28 (2) 管束形成層的季節性……………………………………………………28 (3) 後生木質部……………………………………………………37 (4) 韌皮部……………………………………………………43 (四) 髓部……………………………………………………46 (五) 其他生長現象與季節之關係 (1) 葉芽萌發……………………………………………………47 (2) 花芽萌發……………………………………………………49 六、討論……………………………………………………51 七、引用文獻……………………………………………………60
dc.language.iso	zh-TW
dc.title	芭樂樹幼枝形成層活動之季節性	zh_TW
dc.title	Seasonal Change of Cambial Activity in the Young Branch of Psidium guajava Linn．	en
dc.date.schoolyear	60-2
dc.description.degree	碩士
dc.relation.page	62
dc.rights.note	未授權
dc.contributor.author-dept	生命科學院	zh_TW
dc.contributor.author-dept	植物科學研究所	zh_TW
顯示於系所單位：	植物科學研究所

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