Conductive low cost

In terms of lithium salts for electrolytes of lithium-ion batteries, the main factors are good thermal stability, good electrochemical stability, high ion conductivity, low cost, ease of preparation, and low environmental impact. 

The low cost, light weight, and exceUent electrical conductivity of graphite anodes have made this impressed current protection system valuable for cathodic protection of pipelines, storage vessels, process equipment, and also for weU casings both on- and offshore. 

Electrolyte. The ideal electrolyte, ie, the fluid part of the cell, for organic synthesis would give high solubiHty to the organic, possess good conductivity, have low cost, contain easy recovery and purification, and be noncorrosive. Quaternary ammonium salts provide many of the above criteria ia aqueous systems. A coacise compilation of solveats and salts used ia electroorganic chemistry is available (40). 

Polymer thick films also perform conductor, resistor, and dielectric functions, but here the polymeric resias remain an iategral part after cuting. Owiag to the relatively low (120—165°C) processiag temperatures, both plastic and ceramic substrates can be used, lea ding to overall low costs ia materials and fabrication. A common conductive composition for flexible membrane switches ia touch keyboards uses fine silver particles ia a thermoplastic or thermoset polymeric biader. 

Because of their low thermal conductivity, high temperature capability, low cost, and neutron tolerance, carbon materials make ideal thermal insulators in nuclear reactor environments. For example, the HTTR currently under construction in Japan, uses a baked carbon material (Sigri, Germany grade ASR-ORB) as a thermal insulator layer at the base of the core, between the lower plenum graphite blocks and the bottom floor graphite blocks [47]. 

The main criteria for the selection of the current collector material in a central sulfur cell or for the cell case material in a central sodium cell are corrosion resistance to sulfur and sodium polysulfides, good electrical conductivity, and low costs. This cost argument has led to coated materials which have been compared with nickel—chromium alloys (Inconel 600). 

Nickel Low cost (15-30 cents per square foot) good conductivity (less than 1.0 ohm per square foot) applied by conventional spray equipment easy application relatively stable (differs with manufacturer) easily applied to selected area field repairable. Lesser quality formulations available some are stable, some are not. 

Copper Highly conductive (less than 0.5 ohm per square foot) easy application low cost (15-30 cents per square foot). Oxidation can reduce conductivity (resistance can change to effectively make copper an insulator) some may be alloys—if layered with silver, cost will rise. 

Graphite Low cost (5-15 cents per square foot) easy application excellent ESD (electrostatic discharge) performance. Less conductivity (ranging from 2 ohms to the thousands per square foot, depending upon the amount of graphite) modest shielding capability (up to 30-40 dB). 

Given the actual scenario, one can state that the emerging field of nanotechnology represents new effort to exploit new materials as well as new technologies in the development of efficient and low-cost solar cells. In fact, the technological capabilities to manipulate matter under controlled conditions in order to assemble complex supramolecular structures within the range of 100 nm could lead to innovative devices (nano-devices) based on unconventional photovoltaic materials, namely, conducting polymers, fuUerenes, biopolymers (photosensitive proteins), and related composites. 

Aqueous cathodic electrodeposition has been shown to offer a low-cost route for the fabrication of large surface n-CdS/p-CdTe solar cells. In a typical procedure, CdTe films, 1-2 xm thick, are electrodeposited from common acidic tellurite bath over a thin window layer of a CdS-coated substrate under potential-controlled conditions. The as-deposited CdTe films are stoichiometric, exhibit strong preferential (111) orientation, and have n-type conductivity (doping density typically... 

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