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Split system

Abe, R., Sayama, K., Domen, K., and Arakawa, H. (2001) A new type of water splitting system composed of two different Ti02 photocatalysts (anatase, rutile) and a IOj"/r shuttle redox mediator. Chemical Physics Letters, 344 (3-4), 339-344. [Pg.130]

General Considerations. Some other important considerations that should be made when designing a flow splitting system are listed below. [Pg.765]

Besides the subjects in Table 1, someone would list up radiolysis, which is the water-splitting system by radioactive rays. However, it belongs to a kind of photolysis, and has apprehensions that the produced hydrogen may carry the contaminated radioactivity. [Pg.6]

Carding, Spinning, Weaving Atomizers on RO versus City Water ACP-1, ACP-P. Table I contains the results of an extensive CAM study extending over two weeks in a 100% cotton plant. The plant has a split system using atomizers for supplementary humidification to that provided by an air washer. [Pg.113]

Ohta T (2001) A note on the gas-evolution of mechano-catalytic water splitting system. Int J Hydrogen Energy 26 401... [Pg.111]

Abe R, Sayama K, Domen K, Arakawa H (2001) A new type of water splitting system composed of two different Ti02... [Pg.420]

Before exaxning water splitting by sonophotocatalysis, photocatalysis of H202 was done because the photocatalytic process in the sonophotocatalytic water splitting system was assumed to be due to the decomposition of H202, as... [Pg.114]

Sayama et al.9) and Lincous et al.10) have proposed systems in which water is split by a combination of two photocatalytic and photochemical reactions. The present authors have also studied the water splitting system based on combined photocatalytic systems.u 15) Our goal is the construction of a water splitting system by mimicking the photosynthesis of green plants. [Pg.147]

Fig. 17.8 Energy levels for a water splitting system with a combination of two photocatalytic reactions for oxygen and hydrogen production. Fig. 17.8 Energy levels for a water splitting system with a combination of two photocatalytic reactions for oxygen and hydrogen production.
In addition to the properties of micelles described above, vesicles, which are bilayer structures and can be considered to be model membranes, separate two distinct aqueous phases an entrapped or inner water pool and the bulk aqueous phase. In principle, therefore, electron transfer may be possible across the bilayer and the sites of hydrogen and oxygen production in a water splitting system can be separated spatially. [Pg.528]

Figure 10. An hypothetical model for a cyclic water splitting system, based on a semiconductor particle immobilized in a polymerized membrane and having access to both aqueous solutions on each side of the membrane. Specific and selective coating by catalysts leads to simultaneous and separate hydrogen and oxygen generation on each side of the polymerized membrane. Figure 10. An hypothetical model for a cyclic water splitting system, based on a semiconductor particle immobilized in a polymerized membrane and having access to both aqueous solutions on each side of the membrane. Specific and selective coating by catalysts leads to simultaneous and separate hydrogen and oxygen generation on each side of the polymerized membrane.
Fig. 1 Magnetic anisotropy of a zero-field splitting system S = 3/2, D/k = 20 K... Fig. 1 Magnetic anisotropy of a zero-field splitting system S = 3/2, D/k = 20 K...
Fig. 2 Contribution to the heat capacity of zero-field splitting systems for D/k = 50 K... Fig. 2 Contribution to the heat capacity of zero-field splitting systems for D/k = 50 K...
Zero-field splitting system, anisotropic non-uniform population of a... [Pg.18]

Table 17 General derivation for the zero-field splitting systems... Table 17 General derivation for the zero-field splitting systems...

See other pages where Split system is mentioned: [Pg.18]    [Pg.434]    [Pg.437]    [Pg.9]    [Pg.34]    [Pg.250]    [Pg.273]    [Pg.186]    [Pg.760]    [Pg.4]    [Pg.459]    [Pg.240]    [Pg.241]    [Pg.235]    [Pg.118]    [Pg.217]    [Pg.502]    [Pg.58]    [Pg.59]    [Pg.229]    [Pg.422]    [Pg.25]    [Pg.26]    [Pg.312]    [Pg.117]    [Pg.130]    [Pg.147]    [Pg.300]    [Pg.323]    [Pg.328]    [Pg.522]    [Pg.530]    [Pg.530]    [Pg.102]   
See also in sourсe #XX -- [ Pg.44 ]




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Column Systems, Dilution, and Splitting

Control systems split-range

Cyclic water splitting system

Flow splitting system

Inlet systems split inlets

Light splitting systems

Magnetisation of a zero-field splitting system

Non-oxide Suspended Particle Systems and Direct Water Splitting

Operator splitting techniques in multidimensional systems

Real Ternary System with Phase Splitting Methanol Dehydration

Split Spectrum Tandem Cell Systems

Split flow system

Split injection/flow system

Split-hybrid system

Split-root system

Splitting system

Splitting system

Systems with Liquid-Phase Splitting

Tunneling splitting in a two-level system with pseudo-Jahn-Teller coupling

Water splitting systems

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