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Carbon use efficiency

Monje, O., Bugbee,B- (1998). Adaptation to high CO2 concentration in an optimal environment Radiation capture, canopy quantum yield and carbon use efficiency. Plant Cell Environ., 21, 315-324. [Pg.493]

Table 5.3. Estimates of carbon use efficiency in biomass production... Table 5.3. Estimates of carbon use efficiency in biomass production...
SNR s fluidized-bed cogeneiation system is an early example of the commercial development of AFBC technology. Foster Wheeler designed, fabricated, and erected the coal-fired AFBC/boHer, which generates 6.6 MWe and 37 MW thermal (also denoted as MWt) of heat energy. The thermal energy is transferred via medium-pressure hot water to satisfy the heat demand of the tank farm. The unit bums 6.4 t/h of coal and uses a calcium to sulfur mole ratio of 3 to set the limestone feed rate. The spent bed material may be reiajected iato the bed as needed to maintain or build bed iaventory. The fly ash, collected ia two multicyclone mechanical collectors, may also be transferred pneumatically back to the combustor to iacrease the carbon bumup efficiency from 93%, without fly ash reiajection, to 98%. [Pg.260]

Fig. 5. Water-use efficiency (carbon basis) v. average carbon isotope discrimination in the whole plant, r= -0.88. Open symbols represent well-watered plants and closed symbols represent plants that were droughted. Tifton 8 A, Florunner A, VB187 and +, Chico are cultivars of peanut (Arachis hypogaea). (From Flubick etal., 1986). Fig. 5. Water-use efficiency (carbon basis) v. average carbon isotope discrimination in the whole plant, r= -0.88. Open symbols represent well-watered plants and closed symbols represent plants that were droughted. Tifton 8 A, Florunner A, VB187 and +, Chico are cultivars of peanut (Arachis hypogaea). (From Flubick etal., 1986).
Farquhar, G.D., Hubick, K.T., Condon, A.G. Richards, R.A. (1988). Carbon isotope fractionation and plant water-use efficiency. In Applications of Stable Isotope Ratios to Ecological Research, ed. P.W. Rundel, J.R. Ehleringer K.A. Nagy, pp.21 0. New York Springer-Verlag. [Pg.65]

Farquhar, G.D. Richards, R.A. (1984). Isotopic composition of plant carbon correlates with water-use efficiency of wheat genotypes. Australian Journal of Plant Physiology, 11, 539-52. [Pg.65]

Hubick, K.T. Farquhar, G.D. (1987). Carbon isotope discrimination - selecting for water use efficiency. Australian Cotton Grower 8, 66-8. [Pg.66]

Hubick, K.T., Farquhar, G.D. Shorter,R. (1986). Correlation between water-use efficiency and carbon isotope discrimination in diverse peanut (Arachis) germplasm. Australian Journal of Plant Physiology, 13, 803-16. [Pg.66]

Martin, B.J. Thorstenson, Y.R. (1988). Stable carbon isotope composition (6 C), water use efficiency and biomass productivity of Lycopersicon esculen-tum, Lycopersicon pennellii and the Fi hybrid. Plant Physiology 88, 218-23. [Pg.67]

Masle, J. Farquhar, G.D. (1988). Effects of soil strength on the relation of water use efficiency and growth to carbon isotope discrimination in wheat seedlings. Plant Physiology, 6,147-55. [Pg.67]

A. H. C. M. Schapendonk, P. Dijkstra, J. Groenwold, C. S. Pot, and S. C. Van De Geijn, Carbon balance and water use efficiency of frequently cut Loliuni perenne L. swards at elevated carbon dioxide. Global Change Biol. 5 207 (1997). [Pg.402]

While keeping in mind all these implications, the primary requirement in an attempt to store a huge charge based on the electrostatic forces seems to be high surface area of an activated carbon used. Among different ways of porosity development in carbons, the treatment with an excess of potassium hydroxide is most efficient in terms of microporous texture generation. Porous materials with BET surface areas in excess of 3000 m2/g could be prepared using various polymeric and carbonaceous type precursors [5,6]. [Pg.87]

The assessment of the sustainability of the cultivation of energy crops includes the input and recycling of nutrients, the application of pesticides, the water-use efficiency, the consumption of fossil fuels and the balance of soil carbon. The aim is to recycle the nutrients, which is simple in the case of anaerobic digestion by applying the digestate to the field. If crops are combusted many of the minerals can be returned via the ash. In the case of liquid biofuels, exported nutrients are lost and have to be replaced. The application of pesticides, mainly herbicides, can often be reduced in comparison to food production, but the energy yield per hectare might be reduced if the share of weeds exceeds certain thresholds. Water use efficiency,... [Pg.109]

Carbon 13c/12c 12C = 98.89 13C= 1.11 Organic matter, carbonates, biomineralized tissue, soil, C02 Diet, plant water-use efficiency, climate and habitat, provenance (ivory, marble)... [Pg.179]

Supported metal catalysts are used in a large number of commercially important processes for chemical and pharmaceutical production, pollution control and abatement, and energy production. In order to maximize catalytic activity it is necessary in most cases to synthesize small metal crystallites, typically less than about 1 to 10 nm, anchored to a thermally stable, high-surface-area support such as alumina, silica, or carbon. The efficiency of metal utilization is commonly defined as dispersion, which is the fraction of metal atoms at the surface of a metal particle (and thus available to interact with adsorbing reaction intermediates), divided by the total number of metal atoms. Metal dispersion and crystallite size are inversely proportional nanoparticles about 1 nm in diameter or smaller have dispersions of 100%, that is, every metal atom on the support is available for catalytic reaction, whereas particles of diameter 10 nm have dispersions of about 10%, with 90% of the metal unavailable for the reaction. [Pg.161]

Diels, L., Geets, J., Dejonghe, W., Van Roy, S., and Vanbroekboven, K., 2005b, Heavy metal immobiUzation in groundwater by in sitn bioprecipitation comments and questions about carbon source use, efficiency and sustainability of the process. Consoil 2005, Proceedings of the 9 International FZK/TNO conference on Sod-Water systems,... [Pg.76]

Ci chemistry can no longer be equated only with syngas chemistry. Nature s own C02 photosynthesis and bacterial methane conversion are also Ci conversion processes. We are far from approaching these processes for practical synthetic use efficiently. Production of methane from carbon dioxide (similarly to carbon monoxide) and hydrogen is a feasible process (methanation).80 Similarly, reduction of carbon dioxide with hydrogen to methyl alcohol81 can be readily carried out, and the method has been industrially developed ... [Pg.17]

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See also in sourсe #XX -- [ Pg.741 ]



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