Schematic representation of plant

Figure 2.15 Schematic representation of plant for the manufacture of crude and refined lactose, from sweet whey.

Fig. 3. Principal organization scheme of photosynthesis in plant leaves (Schematic representation of plant oiganellae according to Ref.134)...

Fig. 2. Schematic representation of plant cuticle. A, Surface wax B, cutin embedded in wax C, region containing cutin, wax, and carbohydrate polymers, possibly with very small amounts of protein D, pectin E, cell wall of epidermis.

Fig. 1. A schematic representation of the xylan backbone of arborescent plants, where Xylp = xylopyranosyl unit ...

Fig. 1. (a) Schematic representation of the three types of anoxygenic ([1] and [2]) and oxygenic ([3]) photosynthesis found in plants and bacteria, (b) Phylogenetic tree based on 16S-rRNA sequence comparisons featuring only photo synthetic phyla. 

Fig. 2. Schematic representation of the Ti-plasmid of Agrobacterium, showing the genes involved in transformation of host plants. Note that the genetic map is not to scale in reality, the T-region makes up about 10% of the total plasmid genome (from Bryant, 1988).

Figure 1. Schematic representation of the possible role of PGIP in signalling at the interface between plants and fungi.

Figure 11.1a [1] shows a schematic representation of a micropreparative thin-layer chromatogram obtained on a 0.5-mm Florisil (magnesium silicate) layer prewetted with benzene of a crude extract, i.e., containing coextracted plant oil obtained from Heracleum moelendorfi fruit. The initial band of extract was washed with benzene and then separated by continuous development with ethyl acetate in benzene [1]. As seen from the fraction analysis presented in Figure 11.1b, small quantities of pure bergapten and xanthotoxin can be isolated in this maimer. 

FIGURE 19.7 Schematic representation of a nitrification-denitrification activated sludge plant. 

Figure 23.2 shows a schematic representation of a boiler feedwater treatment system. Raw water from a reservoir, river, lake, borehole or a seawater desalination plant is fed to the steam system. However, it needs to be treated before it can be used for steam generation. The treatment required depends both on the quality of the raw water and the requirements of the utility system. The principal problems with raw water are1,2 ... 

Fig. 12. Schematic representation of how the plant cuticle induces cutinase in a fungal spore... 

Figure 35 Schematic representation of the bioenergetic mechanisms which govern the life cycles in green plants...

Figure 1 is a schematic representation of the wet oxidation micro-pilot plant. The system consists of three sections, an electrically heated oxidation vessel, a high pressure solvent delivery system, and a water cooled depressurization and collection chamber. A more detailed description of the pilot plant can be found in previous publications (3,4). 

Figure 2.10 Schematic representation of a low temperature drying plant for whey (modified from Hynd, 1980).

Figure 21.2 Schematic representation of the general phenylpropanoid, flavonoid, and isoflavonoid pathways in plants (see text for legends).

Figure 9.2. A schematic representation of six reversible-kinetic reactions that are assumed to control the transfer of applied phosphorus (P) between solution, adsorbed, immobilized (chemisorbed), and precipitated phases within the soil. Sinks are shown for irreversible removal of phosphorus from the soil solution by plant uptake and by leaching. [From Mansell et al, (1977a), with permission.]...

Figure 2 Schematic representation of the Eva I-Adam I pilot plant details of heat exchangers, etc., are omitted for clarity (Reproduced by permission homAppl. Catal, 1981,1, 130)...

G-l Schematic representation of the steam methane reforming process, 199 G-2 Estimated investment costs for current and possible future hydrogen plants (with no carbon sequestration) of three sizes, 202... 

Figure 25. Schematic representation of phytoalexin production following exposure of the plant cell wall to a pathogen. E represents plant cell wall and pathogen enzymes M, plant cell messengers.

Figure 2 Schematic representation of a commercial scale plant for the Rhll catalyzed carbonylation of methanol.

Figure 1-1. Schematic representation of a mature mesophyll cell from the leaf of a flowering plant, suggesting some of the complexity resulting from the presence of many membrane-surrounded sub-cellular compartments.

Figure 9-22. Schematic representation of daily changes in the water potentials in the soil, a root, and a leaf of a plant in an initially wet soil that dries over a 1-week period for a rapidly draining sandy soil. TS011 is the water potential in the bulk soil, proot is that in the root xylem, and 4/leaf is the value in a mesophyll cell. Shaded regions indicate night. [Adapted by permission from Slatyer (1967).].

Schematic representation of lytic enzyme action In plant-pathogen Interactions. (Redrawn with permission from Ref. il. Copyright 1988 American Society Plant Physiologists).

Figure I A schematic representation of the small-scale pyrolysis plant.

Figure 7.51. Schematic representation of charge separation in the photosynthetic cycle a) in green plants involving photosystems PS II and PS I and b) in photosynthetic active bacteria (by permission from Rettig, 1986).

Figure 11.5. Schematic representation of an NGCC power plant.

Figure 11.28. Schematic representation of coal-to-hydrogen plant with integrated WGS-membrane cleanup system.

Figure 351. Diagrams representing the three most common heat induration methods and schematic representations of complete pelletizing plants using the particular induration method.(a) Shaft furnace, (b) straight grate, (c) Grate-Kiln. (Courtesy of Boliden Allis, Milwaukee, Wis., USA.)...

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