Phosphide

Indium Phosphide.—Exciting developments in photoelectrochemical cells have come from the Bell Laboratories group, and the material of the year is without doubt p-InP. Heller et al have given details of the first efficient p-type photoelectrochemical cell, p-InP/VCl3-VCl2-HCl/C, with a 9.4% solar conversion efficiency. The success of this cell came as a surprise, since previous studies of InP has suggested that it was rather unstable in aqueous solution. Subsequently Heller et announced an 11.5% solar efficiency for the same cell after [Pg.588]

Heller, B. Miller, and F. A. Thiel, AppL Phys. Lett., 1981, 38, 282. [Pg.588]

Menezes et believe that the p-InP/electrolyte contact is best described as an electrolyte-oxide-semiconductor junction, the oxide layer consisting of indium oxide, possibly in a hydrated form. Electrons can evidently tunnel through the thin ( 2 nm) oxide layer, allowing efficient minority carrier collection by V(III) species in solution. [Pg.589]

Indium Phosphide. Indium phosphide, an important material for high frequency electronic devices, is also of some interest for CdS/lnP heterojunction solar cell applications. The only reported work on the electrodeposition of InP was by Elwell, et al. (71), in 1981. They explored a wide range of solute/soivent systems and developed, for the first time, the conditions necessary for the electrodeposition in inP on [0001 ] CdS and [111] and [100] inP substrates. [Pg.39]

The use of molten salt electrolysis for InP synthesis and growth is complicated by the high volatility of the most convenient sources of In ions (InjOg and InFg) above 650 C, and also by the decomposition of InP at elevated temperatures in an inert atmosphere. These factors limited the temperature regime for stable deposition of InP to 600 - 650°C. [Pg.39]

After trying a number of low melting solvents as listed in Table 2, Elwell, et al. (71), were able to successfully deposit InP from a NaPOg/ KPOg/NaF/KF eutectic mixture named Pofonak . Current densities in the range of 1 - 3 mA/cm were used. [Pg.39]

InP probably forms electrochemically by the following cathode and anode reactions [Pg.39]

The anode used in these experiments was normally graphite, which reacts with the Og evolved to form CO or COg. The minimum deposition [Pg.39]

Rinnen K D, Kolenbramder K D, DeSantolo A M and Mandioh M L 1992 Direst infrared and visible absorption speotrosoopy of stoiohiometrio and nonstoiohiometrio olusters of indium phosphide J. Chem. Phys. 96 4088... [Pg.2406]

Xu C, de Beer E, Arnold D W, Arnold C C and Neumark D M 1994 Anion photoeleotron speotrosoopy of small indium phosphide olusters x, y = 1-4) J. Chem. Phys. 101 5406... [Pg.2406]

Trentler T J ef a/1997 Solution-liquid-solid growth of indium phosphide fibers from organometallic precursors elucidation of molecular and non-molecular components of the pathway J. Am. Chem. Soc. 119 2172... [Pg.2917]

Douglas T and Theopold K H 1991 Molecular precursors for indium phosphide and synthesis of small lll-V semiconductor clusters in solution inorg. Chem. 30 594... [Pg.2917]

TAL SURFACE TREATlffiNTS - CHEMICAL AND ELECTROCHEMICALCONVERSIONTREATlffiNTS] (Vol 16) Titanium phosphide [12037-65-9]... [Pg.998]

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See also in sourсe #XX -- [ Pg.167 ]

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See also in sourсe #XX -- [ Pg.98 ]

See also in sourсe #XX -- [ Pg.34 , Pg.39 ]

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