Lithium titanium phosphate

II. Doped Lithium Titanium Phosphate-Based Ceramic... 

II. DOPED LITHIUM TITANIUM PHOSPHATE-BASED CERAMIC ELECTROLYTES FOR LITHIUM ION BATTERIES... 

Lithium-Ion Conductivity Data of Doped Lithium Titanium Phosphate-Type Ceramic Electrolytes... 

The solid state synthesis process has also been used to study many other variations of doped lithium titanium phosphate solid ionic conductors. The ionic conductivities and compositions of the most promising lithium-ion ceramic electrolytes are shown in Table 26.2. 

Aono, H., Sugimoto, E., Sadaoka, Y., Imanaka, N., and Adachi, G., Ionic condnc-tivity of solid electrolytes based on lithium titanium phosphate, J. Electrochem. Soc., 137, 1023, 1990. 

Aono H, Sugimoto E, Sadaoka Y, Imanaka N, Adachi G (1990) Ionic conductivity of solid electrol5ne based on lithium titanium phosphate. J Electrochem Soc 137 1023... 

Ooi, K., Miyai, Y., Makita, Y, and Kanoh, H., Fractionation of lithium isotopes in ion exchange chromatography with titanium phosphate exchanger, Separation Sci. Technol., 34, 1133, 1999. 

Appreciable ionic conductivity is found in open framework or layered materials containing mobile cations (see Ionic Conductors). Several phosphates have been found to be good ionic conductors and are described above NASICON (Section 5.2.1), a-zirconium phosphates (Section 5.3.1), HUP (Section 5.3.3), and phosphate glasses (Section 5.4). Current interest in lithium ion-conducting electrolytes for battery apphcations has led to many lithium-containing phosphate glasses and crystalline solids such as NASICON type titanium phosphate being studied. ... 

Charge Rate Nickel Cobalt Manganese Oxide % Ah to Clamp Voltage Iron Phosphate Lithium Titanium Oxide... 

The aims of the addition of inert ceramic filler to the electrospun polymer fiber matrix to form polymer/ceramic composite fiber membrane for separator in LIB were on one hand to prevent dimensional changes by thermal deformation at high temperature because of the frame structure of the heat-resistant ceramic powder and on the other hand to increase the ionic conductivity of the membrane due to the intrinsic ionic conductivity of the ceramics. Various ceramic fillers had been incorporated into the electrospun polymer membranes to make composite separators, including aluminum oxide (AI2O3) [61], fumed silica (SiOa) [29,48,62], titanium dioxide (Ti02) [50, 63-65], lithium lanthanum titanate oxide (LLTO) [51], and lithium aluminum titanium phosphate (LATP) [52],... 

NAIRN,K.M., BEST, A.S., NEWMAN, P.J., MACFARLANE,D.R. and FORSYTH, M., 1999. Ceramic-polymer interface in composite electrolytes of lithium aluminium titanium phosphate and polyetherurethane polymer electrolyte. Solid State Ionics, 121(1 ), 115-119. 

Fluor-jod, n. iodine fluoride, -kalium, n. potassium fluoride, -kalzium, n. calcium fluoride, -kiesel, m. silicon fluoride, -kie-selsaure,/. fluosilicic acid, -kohlenstoff, m. carbon fluoride, -lithium, n. lithium fluoride. -metall, n. metallic fluoride, -natrium, n. sodium fluoride, -phosphat, n. fluophosphate. -phosphor, m. phosphorus fluoride, -salz, n. fluoride, -schwefel, m. sulfur fluoride, -selen, n. selenium fluoride, -silber, n. silver fluoride, -silikat, n. fluo-silicate. -silizium, n. silicon fluoride, -sili-ziumverbindung, /. fluosilicate. -tantal-sMure, /. fluotantalic acid, -tellur, n. tellurium fluoride, -titan, n. titanium fluoride, -toluol, n. fluorotoluene, fluotoluene. 

The present preparation illustrates a general and convenient method for a two-step deoxygenation of carbonyl compounds to olefins. Related procedures comprise the basic decomposition of p-toluenesulfonylhydrazones, the hydride reduction of enol ethers, enol acetates, enamines, the reduction of enol phosphates (and/or enol phosphorodiamidates) by lithium metal in ethylamine (or liquid ammonia),the reduction of enol phosphates by titanium metal... 

Deoxygenation of phenols. The reduction of enol phosphates to alkenes by titanium metal (8,482) has been extended to reduction of aryl diethyl phosphates to arenes. Yields are in the range 75-95% reduction with lithium in liquid ammonia (1, 248) usually proceeds in low yield. 

When refractory linings are intended to contain moderate to high temperature environments having products of combustion or reaction containing compounds of sodium, lithium, potassium, vanadium and titanium and bromides, fluorides, chlorides, sulfides, phosphates along with the usual CO2, CO, H2, and O2, extreme care must be taken in their design. In these highly corrosive atmospheres, refractories perform differently than they do in clean environments. 

Conversion of ketones into olefins (3, 98). This reaction can be effected by conversion to the thermodynamically controlled enol phosphate with diethyl phosphorochloridate in TMEDA followed by reduction. Originally lithium in NH3 or C2H5NH2 was used for this step. Titanium metal is more effective, except for ketones conjugated to aromatic rings. ... 

The cleavage of carbon-oxygen bonds from alkenyl or aryl phosphates can be accomplished under reductive conditions with a low valent metal. As vinyl phosphates can be formed readily from ketones, this procedure provides a method to convert a ketone to an alkene. For example, the alkenyl phosphate 74 was prepared by trapping the enolate formed on reduction of the enone 73 and was converted into the alkene 75 (7.55). The chemistry therefore provides a method to prepare structurally specihc alkenes. Low-valent titanium (prepared for example by reduction of titanium(III) chloride with potassium metal) is a convenient alternative to lithium or sodium in liquid ammonia or an amine for the reductive cleavage of alkenyl or aryl phosphates. 

Hypochlorites of sodium, calcium, and lithium, and chlorinated trisodium phosphate involve chlorine in their production. Sodium hypochlorite of about 5% strength finds extensive use in the household bleach market and in residential swimming pools, and 15% sodium hypochlorite, an industrial bleach, is used for water treatment in municipal and industrial plants. Sodium hypochlorite is made by reacting chlorine with caustic soda. Calcium hypochlorite is mainly used as a swimming pool chemical. Aluminum chloride, produced from chlorine and aluminum or alumina, is used as a catalyst (for alkyl and ethyl benzenes, dyestuffs, ethyl chloride, and hydrocarbon resin production) and also in the production of pharmaceuticals and titanium dioxide. 

A well-formulated product will ensure a level of fluoride in the saliva above 0.02 ppm for several hours [18]. Fluoride ions are present in toothpaste formulations largely in the form of stannous fluoride (Snp2), sodium monofluorophosphate (NajPOsF), and sodium fluoride (NaF). But we can also find in the literature potassium fluoride, lithium fluoride, aluminum fluoride, zinc fluoride, acidic phosphate fluoride, ammonium fluoride, titanium tetrafluoride, and amine fluoride. 

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