Artykuły w czasopismach: „Ecophysiology”

1

Lüttge, Ulrich, i Fabio R. Scarano. "Ecophysiology". Revista Brasileira de Botânica 27, nr 1 (marzec 2004): 1–10. http://dx.doi.org/10.1590/s0100-84042004000100001.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

2

Jones, Hamlyn G. "Ecophysiology". Trends in Plant Science 1, nr 4 (kwiecień 1996): 129–30. http://dx.doi.org/10.1016/s1360-1385(96)90009-6.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

3

Collins, Chris. "Plant ecophysiology". Crop Protection 17, nr 2 (marzec 1998): 185. http://dx.doi.org/10.1016/s0261-2194(97)00106-3.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

4

Robinson, David. "Comparative ecophysiology?" New Phytologist 146, nr 3 (czerwiec 2000): 389–90. http://dx.doi.org/10.1046/j.1469-8137.2000.00655.x.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

5

Humphreys, Mike W. "Plant ecophysiology". New Phytologist 155, nr 2 (sierpień 2002): 202–3. http://dx.doi.org/10.1046/j.1469-8137.2002.00461_4.x.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

6

Boyd, C. E. "Fish ecophysiology". Aquaculture 114, nr 3-4 (sierpień 1993): 361–62. http://dx.doi.org/10.1016/0044-8486(93)90312-m.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

7

Berlinsky, David. "Fish ecophysiology". Aquatic Toxicology 30, nr 4 (grudzień 1994): 381–82. http://dx.doi.org/10.1016/0166-445x(94)00055-7.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

8

Merrett, P. "Ecophysiology of Spiders". Journal of Arid Environments 13, nr 1 (lipiec 1987): 91a—92. http://dx.doi.org/10.1016/s0140-1963(18)31157-1.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

9

De Costa, W. A. Janendra M., A. Janaki Mohotti i Madawala A. Wijeratne. "Ecophysiology of tea". Brazilian Journal of Plant Physiology 19, nr 4 (grudzień 2007): 299–332. http://dx.doi.org/10.1590/s1677-04202007000400005.

Pełny tekst źródła

Streszczenie:

Tea [Camellia sinensis (L.) O. Kuntze] is one of the most important beverage crops in the world. The major tea-growing regions of the world are South-East Asia and Eastern Africa where it is grown across a wide range of altitudes up to 2200 m a.s.l.. This paper reviews the key physiological processes responsible for yield determination of tea and discusses how these processes are influenced by genotypic and environmental factors. Yield formation of tea is discussed in terms of assimilate supply through photosynthesis and formation of harvestable sinks (i.e. shoots). The photosynthetic apparatus and partial processes (i.e. light capture, electron transport and carboxylation) of tea show specific adaptations to shade. Consequently, maximum light-saturated photosynthetic rates of tea are below the average for C3 plants and photoinhibition occurs at high light intensities. These processes restrict the source capacity of tea. Tea yields are sink-limited as well because shoots are harvested before their maximum biomass is reached in order to maintain quality characters of made tea. In the absence of water deficits, rates of shoot initiation and extension are determined by air temperature and saturation vapour pressure deficit, with the former having positive and the latter having negative relationships with the above rates. During dry periods, when the soil water deficit exceeds a genotypically- and environmentally-determined threshold, rates of shoot initiation and extension are reduced with decreasing shoot water potential. Tea yields respond significantly to irrigation, a promising option to increase productivity during dry periods, which are experienced in many tea-growing regions.

Style APA, Harvard, Vancouver, ISO itp.

10

Duffey, Eric. "Ecophysiology of spiders". Biological Conservation 43, nr 3 (1988): 242–43. http://dx.doi.org/10.1016/0006-3207(88)90117-6.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

11

Bartak, M., V. Dvorak, J. Kalina, J. A. Bourret, L. Burketova, M. Cervena, F. Fric i in. "Section 1 - Ecophysiology". Biologia plantarum 34, Suppl.1 (1.01.1992): 489–95. http://dx.doi.org/10.1007/bf02930802.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

12

Aktan, N., N. Palavan-Unsal, A. V. Andonov, K. M. Georgieva, I. T. Yordanov, L. Atanasiu, E. Petcu i in. "Session 17 Ecophysiology". Biologia plantarum 36, Suppl.1 (1.01.1994): S257—S307. http://dx.doi.org/10.1007/bf02931129.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

13

Tomasi, Thomas E., Briana N. Anderson i Theodore Garland. "Ecophysiology of mammals". Journal of Mammalogy 100, nr 3 (23.05.2019): 894–909. http://dx.doi.org/10.1093/jmammal/gyz026.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

14

Senger, Horst. "Ecophysiology of photosynthesis". Journal of Photochemistry and Photobiology B: Biology 28, nr 2 (maj 1995): 175. http://dx.doi.org/10.1016/1011-1344(95)90135-3.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

15

Lombard, Fabien, Florent Renaud, Christopher Sainsbury, Antoine Sciandra i Gabriel Gorsky. "Appendicularian ecophysiology I". Journal of Marine Systems 78, nr 4 (listopad 2009): 606–16. http://dx.doi.org/10.1016/j.jmarsys.2009.01.004.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

16

Kapos, Valerie, S. S. Mulkey, R. L. Chazdon i A. P. Smith. "Tropical Forest Plant Ecophysiology." Journal of Applied Ecology 34, nr 3 (czerwiec 1997): 831. http://dx.doi.org/10.2307/2404930.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

17

Hawthorne, William D., S. S. Mulkey, R. L. Chazdon i A. P. Smith. "Tropical Forest Plant Ecophysiology." Journal of Ecology 85, nr 1 (luty 1997): 105. http://dx.doi.org/10.2307/2960636.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

18

Skillman, John, Stephen S. Mulkey, Robin L. Chazdon i Alan P. Smith. "Tropical Forest Plant Ecophysiology." Ecology 78, nr 3 (kwiecień 1997): 965. http://dx.doi.org/10.2307/2266080.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

19

Santos Matos, Fábio. "Ecophysiology Of Leaf Senescence". Agronomy & Agricultural Science 3, nr 1 (13.03.2020): 1–6. http://dx.doi.org/10.24966/aas-8292/100020.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

20

Baird, Donald J., T. Braunbeck, W. Hanke i H. Segner. "Fish Ecotoxicology and Ecophysiology". Journal of Animal Ecology 63, nr 4 (październik 1994): 1007. http://dx.doi.org/10.2307/5279.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

21

Morison, J. I. L. "P3 General Plant Ecophysiology". Journal of Experimental Botany 47, supp1 (1.05.1996): 37–48. http://dx.doi.org/10.1093/oxfordjournals.jxb.a022914.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

22

Kolb, Thomas E. "ecophysiology of coniferous forests". Forest Ecology and Management 82, nr 1-3 (kwiecień 1996): 254. http://dx.doi.org/10.1016/s0378-1127(96)90010-9.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

23

Spellerberg, Ian F. "Ecophysiology of Desert Vertebrates". Journal of Arid Environments 17, nr 3 (listopad 1989): 357–58. http://dx.doi.org/10.1016/s0140-1963(18)30892-9.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

24

Cloudsley-Thompson, J. L. "Ecophysiology of Desert Reptiles". Journal of Arid Environments 15, nr 2 (listopad 1988): 215. http://dx.doi.org/10.1016/s0140-1963(18)30995-9.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

25

Turner, Ian M. "Tropical forest plant ecophysiology". Trends in Ecology & Evolution 11, nr 12 (grudzień 1996): 518–19. http://dx.doi.org/10.1016/0169-5347(96)88904-x.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

26

Bickford, Christopher P. "Ecophysiology of leaf trichomes". Functional Plant Biology 43, nr 9 (2016): 807. http://dx.doi.org/10.1071/fp16095.

Pełny tekst źródła

Streszczenie:

This review examines how leaf trichomes influence leaf physiological responses to abiotic environmental drivers. Leaf trichomes are known to modulate leaf traits, particularly radiation absorptance, but studies in recent decades have demonstrated that trichomes have a more expansive role in the plant–environment interaction. Although best known as light reflectors, dense trichome canopies modulate leaf heat balance and photon interception, and consequently affect gas exchange traits. Analysis of published studies shows that dense pubescence generally increases reflectance of visible light and near-infrared and infrared radiation. Reflective trichomes are also protective, reducing photoinhibition and UV-B related damage to leaf photochemistry. Little support exists for a strong trichome effect on leaf boundary layer resistance and transpiration, but recent studies indicate they may play a substantive role in leaf water relations affecting leaf wettability, droplet retention and leaf water uptake. Different lines of evidence indicate that adaxial and abaxial trichomes may function quite differently, even within the same leaf. Overall, this review synthesises and re-examines the diverse array of relevant studies from the past 40 years, illustrating our current understanding of how trichomes influence the energy, carbon and water balance of plants, and highlighting promising areas for future research.

Style APA, Harvard, Vancouver, ISO itp.

27

Gloser, J. "Ecophysiology of Tropical Intercropping". Biologia plantarum 38, nr 4 (1.12.1996): 562. http://dx.doi.org/10.1007/bf02890607.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

28

Kirst, Gunter O., i Christian Wiencke. "ECOPHYSIOLOGY OF POLAR ALGAE". Journal of Phycology 31, nr 2 (kwiecień 1995): 181–99. http://dx.doi.org/10.1111/j.0022-3646.1995.00181.x.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

29

Shu, Fukai. "Ecophysiology of tropical intercropping". Field Crops Research 47, nr 1 (lipiec 1996): 78–79. http://dx.doi.org/10.1016/0378-4290(96)81478-x.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

30

Sayer, M. D. J. "Fish: Ecotoxicology and ecophysiology". Journal of Experimental Marine Biology and Ecology 173, nr 2 (listopad 1993): 294–95. http://dx.doi.org/10.1016/0022-0981(93)90061-r.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

31

Przybyłowicz, W. J., J. Mesjasz-Przybyłowicz, P. Migula, M. Nakonieczny, M. Augustyniak, M. Tarnawska, K. Turnau i in. "Micro-PIXE in ecophysiology". X-Ray Spectrometry 34, nr 4 (2005): 285–89. http://dx.doi.org/10.1002/xrs.826.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

32

Duan, Chensong, Zhifeng Wu, Hu Liao i Yin Ren. "Interaction Processes of Environment and Plant Ecophysiology with BVOC Emissions from Dominant Greening Trees". Forests 14, nr 3 (7.03.2023): 523. http://dx.doi.org/10.3390/f14030523.

Pełny tekst źródła

Streszczenie:

In global greening, biogenic volatile organic compound (BVOC) emissions and their influencing factors have been considered due to their significant roles in the biosphere and atmosphere. Many studies have reported relationships of BVOC emissions with environmental factors and plant ecophysiology. However, the direct and indirect effects of environmental factors on BVOC emissions remain unclear, and the causal relationships between plant ecophysiology and BVOC emissions are ambiguous. We measured the isoprene and monoterpene emissions from dominant greening plants using a dynamic enclosure system and quantified the interactions of environment–-plant and ecophysiology–BVOC emissions using a path analysis model. We found that isoprene emission was directly affected by photosynthetic rate, and indirectly affected by photosynthetically active radiation and air temperature (Tair). Monoterpene emissions were directly affected by atmospheric pressure, relative air humidity and specific leaf weight, and indirectly affected by Tair.

Style APA, Harvard, Vancouver, ISO itp.

33

Miller-Goodman, Mary S. "Grassland Ecophysiology and Grazing Ecology." Crop Science 42, nr 3 (2002): 981. http://dx.doi.org/10.2135/cropsci2002.0981.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

34

Crafts‐Brandner, Steven J. "Handbook of Plant Ecophysiology Techniques". Crop Science 42, nr 4 (lipiec 2002): 1387–88. http://dx.doi.org/10.2135/cropsci2002.1387a.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

35

Miller‐Goodman, Mary S. "Grassland Ecophysiology and Grazing Ecology". Crop Science 42, nr 3 (maj 2002): 981–82. http://dx.doi.org/10.2135/cropsci2002.9810.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

36

Close, Dugald C., i Christopher L. Beadle. "The Ecophysiology of Foliar Anthocyanin". Botanical Review 69, nr 2 (kwiecień 2003): 149–61. http://dx.doi.org/10.1663/0006-8101(2003)069[0149:teofa]2.0.co;2.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

37

Campostrini, Eliemar, i David M. Glenn. "Ecophysiology of papaya: a review". Brazilian Journal of Plant Physiology 19, nr 4 (grudzień 2007): 413–24. http://dx.doi.org/10.1590/s1677-04202007000400010.

Pełny tekst źródła

Streszczenie:

Papaya (Carica papaya L.) is a principal horticultural crop of tropical and subtropical regions. Knowledge of how papaya responds to environmental factors provides a scientific basis for the development of management strategies to optimize fruit yield and quality. A better understanding of genotypic responses to specific environmental factors will contribute to efficient agricultural zoning and papaya breeding programs. The objective of this review is to present current research knowledge related to the effect of environmental factors and their interaction with the photosynthetic process and whole-plant physiology. This review demonstrates that environmental factors such as light, wind, soil chemical and physical characteristics, temperature, soil water, relative humidity, and biotic factors such as mycorrhizal fungi and genotype profoundly affect the productivity and physiology of papaya. An understanding of the environmental factors and their interaction with physiological processes is extremely important for economically sustainable production in the nursery or in the field. With improved, science-based management, growers will optimize photosynthetic carbon assimilation and increase papaya fruit productivity and quality.

Style APA, Harvard, Vancouver, ISO itp.

38

Almeida, Alex-Alan F. de, i Raúl R. Valle. "Ecophysiology of the cacao tree". Brazilian Journal of Plant Physiology 19, nr 4 (grudzień 2007): 425–48. http://dx.doi.org/10.1590/s1677-04202007000400011.

Pełny tekst źródła

Streszczenie:

Cacao, one of the world's most important perennial crops, is almost exclusively explored for chocolate manufacturing. Most cacao varieties belong to three groups: Criollo, Forastero and Trinitario that vary according to morphology, genetic and geographical origins. It is cropped under the shade of forest trees or as a monocrop without shade. Seedlings initially show an orthotropic growth with leaf emission relatively independent of climate. The maturity phase begins with the emission of plagiotropic branches that form the tree crown. At this stage environmental factors exert a large influence on plant development. Growth and development of cacao are highly dependent on temperature, which mainly affects vegetative growth, flowering and fruit development. Soil flooding decreases leaf area, stomatal conductance and photosynthetic rates in addition to inducing formation of lenticels and adventitious roots. For most genotypes drought resistance is associated with osmotic adjustment. Cacao produces caulescent flowers, which begin dehiscing in late afternoon and are completely open at the beginning of the following morning releasing pollen to a receptive stigma. Non pollinated flowers abscise 24-36 h after anthesis. The percentage of flowers setting pods is in the range 0.5 - 5%. The most important parameters determinants of yield are related to: (i) light interception, photosynthesis and capacity of photoassimilate distribution, (ii) maintenance respiration and (iii) pod morphology and seed fermentation, events that can be modified by abiotic factors. Cacao is a shade tolerant species, in which appropriate shading leads to relatively high photosynthetic rates, growth and seed yield. However, heavy shade reduces seed yield and increases incidence of diseases; in fact, cacao yields and light interception are tightly related when nutrient availability is not limiting. High production of non-shaded cacao requires high inputs in protection and nutrition of the crop. Annual radiation and rainfall during the dry season explains 70% of the variations in annual seed yields.

Style APA, Harvard, Vancouver, ISO itp.

39

Wilkins, R. J. "Grassland Ecophysiology and Grazing Ecology". Grass and Forage Science 56, nr 2 (29.06.2001): 201–2. http://dx.doi.org/10.1046/j.1365-2494.2001.00256.x.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

40

Jones, H. G., N. Archer, E. Rotenberg i R. Casa. "Radiation measurement for plant ecophysiology". Journal of Experimental Botany 54, nr 384 (1.03.2003): 879–89. http://dx.doi.org/10.1093/jxb/erg116.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

41

Buskirk, Ruth E. "Ecophysiology of Spiders. Wolfgang Nentwig". Quarterly Review of Biology 62, nr 4 (grudzień 1987): 452. http://dx.doi.org/10.1086/415670.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

42

Südekum, Karl-Heinz. "Grassland Ecophysiology and Grazing Ecology". Animal Feed Science and Technology 94, nr 3-4 (grudzień 2001): 208–9. http://dx.doi.org/10.1016/s0377-8401(01)00291-7.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

43

FEILD, TAYLOR S., i NAN CRYSTAL ARENS. "The ecophysiology of early angiosperms". Plant, Cell & Environment 30, nr 3 (11.01.2007): 291–309. http://dx.doi.org/10.1111/j.1365-3040.2006.01625.x.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

44

Lamont, Byron B., Roy Wittkuhn i Dylan Korczynskyj. "Ecology and ecophysiology of grasstrees". Australian Journal of Botany 52, nr 5 (2004): 561. http://dx.doi.org/10.1071/bt03127.

Pełny tekst źródła

Streszczenie:

‘Xanthorrhoea…is in habit one of the most remarkable genera of Terra Australis, and gives a peculiar character to the vegetation of that part of the country where it abounds’ Robert Brown (1814). Grasstrees (arborescent Xanthorrhoea, Dasypogon, Kingia), with their crown of long narrow leaves and blackened leafbase-covered trunk (caudex), are a characteristic growth form in the Australian flora. Xanthorrhoea is the most widespread genus, with 28 species that are prominent from heathlands to sclerophyll forests. While leaf production for X. preissii reaches a peak in spring–summer, growth never stops even in the cool winter or dry autumn seasons. Summer rain, accompanied by a rapid rise in leaf water potential, may be sufficient to stimulate leaf production, whereas root growth is confined to the usual wet season. Grasstrees are highly flammable yet rarely succumb to fire: while retained dead leaves may reach >1000°C during fire, the temperature 100 mm above the stem apex remains <60°C and the roots are insulated completely. Immediately following fire, leaf production from the intact apical meristem is up to six times greater than that at unburnt sites. For X. preissii, pre-fire biomass is restored within 40 weeks; the mass of live leaves remains uniform from thereon, whereas the mass of dead leaves increases steadily. Leaves usually survive for >2 years. In X. preissii, the post-fire growth flush corresponds to a reduction in starch storage by desmium in the caudex. Minerals, especially P, are remobilised from the caudex to the crown following a spring fire, but accumulate there following an autumn fire. At least 80% of P is withdrawn from senescing leaves, while >95% K and Na are leached from dead leaves. Most stored N and S are volatilised by fire, with 1–85% of all minerals returned as ash. Despite monthly clipping for 16 months, X. preissii plants recover, although starch reserves are depleted by 90%, indicating considerable resilience to herbivory. Analysis of colour band patterns in the leafbases of X. preissii shows that elongation of the caudex may vary more than 5–50 mm per annum, with 10–20 mm being typical. Exceptionally tall plants (>3 m) may reach an age of 250 years, with a record at 450 years (6 m). Fires, recorded as black bands on the leafbases, in south-western Australia have been decreasing in frequency but increasing in variability since 1750–1850. Some grasstrees have survived a mean fire interval of 3–4 years over the last two centuries. In more recent times, some grasstrees have not been burnt for >50 years. The band-analysis technique has been used to show a downward trend in plant δ13C of 2–5.5‰ from 1935 to the present. Grasstrees are most likely to flower in the first spring after fire. A single inflorescence is initiated from the apical meristem, elongating at up to 100 mm day–1 and reaching a length up to 3 m, with one recorded at 5.5 m. This rapid rate of elongation is achieved through leaf (and inflorescence) photosynthesis and desmium starch mobilisation. The developing spike and seeds are vulnerable to a moth larva. Leaf production recommences from axillary buds and the trade-off with reproduction is equivalent to 240 leaves in X. preissii. Flowering and seed production are affected by time of fire. Grasstrees are mainly insect-pollinated. Up to 8000 seeds per spike are produced, although pre-dispersal granivory is common. Seeds are released in autumn and persist in the soil for <2 years. Most fresh seeds germinate in the laboratory but germination is inhibited by light. At any time, seedlings and juveniles may account for most plants in the population, although there may be up to an 80% reduction within 1 year of seedling emergence, often due to kangaroo herbivory. In the absence of fire, mortality of adults may be 4% per annum. Although few grasstree species are considered rare or threatened, their conservation requirements, especially in regard to a suitable fire regime, remain unknown. Grasstrees are particularly susceptible to the exotic root pathogen, Phytophthora cinnamomi, although recruitment among some species has been observed 20–30 years after pathogen invasion. Much remains to be known about the biology of this icon of the Australian bush.

Style APA, Harvard, Vancouver, ISO itp.

45

Manczinger, L., Zs Antal i L. Kredics. "Ecophysiology and breeding of mycoparasiticTrichodermastrains". Acta Microbiologica et Immunologica Hungarica 49, nr 1 (marzec 2002): 1–14. http://dx.doi.org/10.1556/amicr.49.2002.1.1.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

46

Alberdi, Miren, León A. Bravo, Ana Gutiérrez, Manuel Gidekel i Luis J. Corcuera. "Ecophysiology of Antarctic vascular plants". Physiologia Plantarum 115, nr 4 (11.07.2002): 479–86. http://dx.doi.org/10.1034/j.1399-3054.2002.1150401.x.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

47

Raven, John A., i Catriona L. Hurd. "Ecophysiology of photosynthesis in macroalgae". Photosynthesis Research 113, nr 1-3 (28.07.2012): 105–25. http://dx.doi.org/10.1007/s11120-012-9768-z.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

48

DaMatta, Fábio M. "Ecophysiology of tropical tree crops: an introduction". Brazilian Journal of Plant Physiology 19, nr 4 (grudzień 2007): 239–44. http://dx.doi.org/10.1590/s1677-04202007000400001.

Pełny tekst źródła

Streszczenie:

In this special issue, ecophysiology of major tropical tree crops, considered here on a broader sense and including species such as banana, cashew, cassava, citrus, cocoa, coconut, coffee, mango, papaya, rubber, and tea, are examined. For most of these crops, photosynthesis is treated as a central process affecting growth and crop performance. The crop physiological responses to environmental factors such as water availability and temperature are highlighted. Several gaps in our database concerning ecophysiology of tropical tree crops are indicated, major advances are examined, and needs of further researches are delineated.

Style APA, Harvard, Vancouver, ISO itp.

49

Tognetti, Roberto, i John D. Marshall. "Relationship between Forest Ecophysiology and Environment". Forests 12, nr 1 (9.01.2021): 68. http://dx.doi.org/10.3390/f12010068.

Pełny tekst źródła

Streszczenie:

Although aspects of forest ecophysiology and forest environments have received considerable attention from research scientists in the last three decades, assessment of implications for meeting the climate targets and international agreements is still a matter of debate [...]

Style APA, Harvard, Vancouver, ISO itp.

50

Mann, Kenneth H. "Seaweeds: Their environment, biogeography, and ecophysiology". Limnology and Oceanography 36, nr 5 (lipiec 1991): 1066. http://dx.doi.org/10.4319/lo.1991.36.5.1066.

Pełny tekst źródła

Style APA, Harvard, Vancouver, ISO itp.

Artykuły w czasopismach na temat „Ecophysiology”

Utwórz poprawne odniesienie w stylach APA, MLA, Chicago, Harvard i wielu innych