Amount Of Precious Metals Research Articles

Ce enhanced RuNi alloy multi-metal synergic hydrotalcite oxide derived catalyst for high performance CO2 methanation

Ni-based methanation catalysts have problems such as low temperature activity and easy sintering. The high cost of supported Ru-based methanation catalysts limits their application in industrialization. In this work, a hydrotalcite precursor Ru-Ni-Ce-Y catalyst was prepared by co-precipitation method, and the hydrotalcite oxide catalyst was prepared by high temperature calcination. The hydrotalcite oxide catalyst was prepared by optimizing the ratio of Ni element and the amount of precious metal and rare earth metal. Compared with the traditional supported catalyst, the activity of Ru1Ni80Ce4Y20 was significantly improved. It is confirmed from the experimental results that the medium basic sites, oxygen vacancies and the synergistic effect between RuNi alloy and Ce are the reasons for the high performance of Ru1Ni80Ce4Y20. It provides a thought for the design of highly active, stable and low cost methanation catalysts in industrial methanation production.

Wealth or Just Job Seekers: Medieval Skeletal Series from Kutná Hora-Sedlec (Czech Republic) with a Notable Surplus of Men

Kutná Hora entered the 14th century as a rich, prosperous, and densely-populated city producing tons of silver. Such an amount of precious metal could not be mined and processed without an influx of people from other cities and rural areas and without the contribution of skilled specialists from abroad. Despite the apparent wealth of the city, its inhabitants (either settled or newly arrived) experienced and died during mortality crises. Evidence of such events was discovered in the Kutná Hora suburbs, where the medieval burial ground, including a significant component of mass burials, has been unearthed. In the data derived from pooled catastrophic and non-catastrophic burials (n=1785 individuals), a notable surplus of males has been identified with a striking imbalanced adult sex ratio of 149. After considering factors potentially influencing this value, we suggest that the figure likely mirrors the original population composition as a consequence of the inflow of men migrating to the town for labour/economic opportunities.

Recovering valuable metals from Waste Printed Circuit Boards (WPCB): A short review

In the modern era, metal usage can be traced in almost anything from simple household tools to complex electronic equipment. About 95 % of the electronic equipment surrounding us is built using components containing valuable metals, such as gold, silver, copper, palladium, and rare earths. Recycling electronic equipment offers a much richer resource than extracting metals from their respective ores. Printed circuit boards (PCBs) form about 3–6 % of the total electronic waste yet contain considerable quantities of precious metals. Most of the electronic waste (e-waste) that is disposed of, such as computers, mobile phones, televisions, printers, etc., are equipped with PCBs. These products are equipped with printed circuit boards(PCB) which are rich in valuable metals, including copper, aluminium, and gold. Recycling e-waste, especially PCBs, provides a route for economical and profitable extraction of valuable metals other than mining. Waste PCBs can be recycled using mechanical, pyrometallurgical, hydrometallurgical, electrometallurgical, and biometallurgical processes. In this review, the different technologies available for PCB recycling are compared, their limitations are highlighted to appreciate an environmentally friendly recovery of metals from the WPCBs. The PCBs feature a complex composition; therefore, it requires an intricate and novel approach to extract the specific metals. The review briefly analyses the different methods and techniques to extract the constituent elements and serves as a reliable reference for recycling WPCBs.

Processing of anode slime with deep eutectic solvents as a green leachant

This paper describes an efficient process of recovering valuable metals from a copper anode slime sample using green chemicals such as choline chloride (ChCl) based deep eutectic solvents (DESs). The leaching agents include ChCl-urea, ChCl-ethylene glycol, ChCl-urea-ethylene glycol and ChCl/urea-deionized water in a 1:2, 1:2, 1:0.5:1.5, and 1:1 ratio, respectively. Prior to leaching experiments, chemical and mineralogical characterization of copper anode slime was performed. Considerable amount of precious metals was detected in the copper anode slime by chemical analysis. The main phases of copper anode slime detected by XRD and SEM/EDX analysis were namely Cu2O, SnO2, and, PbSO4. After leaching experiments, 97% of copper was recovered from the copper anode slime using ChCl-urea under an optimum condition at 95 °C of reaction temperature, 4 h reaction duration and, 1/25 g/mL solid/liquid ratio. The results showed that 91% of silver was extracted from the anode slime under the optimum condition with ChCl-urea DES composition, 95 °C reaction temperature, 48 h reaction duration, and 1/10 solid/liquid ratio. Gold was not leachable in the experiment using ChCl based DES with hydrogen bonding reagents such as urea and ethylene glycol. Moreover, the results revealed that PbSO4 was very soluble in DES prepared by ChCl and urea.

Characterization of end-of-life mobile phone printed circuit boards for its elemental composition and beneficiation analysis

ABSTRACT Globally, waste electrical and electronic equipment is one of the fastest-growing waste sectors. Mobile phones constitute the major portion of the telecommunication e-waste category. Over the years, waste mobile phones were considered as a potential source of secondary metals. This study aims to determine the physical and chemical composition of the discarded mobile phones and to evaluate its recovery potential. The printed circuit boards from the discarded (waste) mobile phones (MPCB) were collected and samples of different sizes 3 × 3 cm, 2 mm, 1 mm, 500 µm, and 150 µm were obtained after milling and sieving. Elemental composition revealed the presence of base metals, Cu, Zn, Fe, Ni, and Pb, in higher quantities with a significant amount of precious metals Au and Ag. Amount of base metals present in different MPCB size fractions was found in the order 3 × 3 cm > 2 mm > 1 mm > 500 µm >150 µm. The amount of precious metals like Ag and Au was found to be higher in large-sized MPCB fractions. FTIR studies declared the presence of polymers like ABS, PC, and HIPs in MPCB samples. TCLP tests for toxic metals revealed that MPCBs contained high concentrations of cadmium, lead, and mercury highlighting their hazardous potential. The ultimate analysis revealed that NMF has a GCV of 12.34 MJ/kg and a volatile content of 42.25%, which can be a potential source of energy that can be recovered through the gasification or pyrolysis process. Overall, the comprehensive characterization of waste MPCBs will systematically provide a better understanding of e-waste recycling processes for beneficiation purpose and sustainable resource utilization. Implications: A comprehensive characterization of waste mobile phone printed circuit boards for its elemental composition was performed. Mechanical treatment steps before MPCBs processing increased the exposure of metals resulting in a higher concentration of metals in acid-digested samples. The elemental analysis of MPCBs revealed that MPCBs possessed significant quantities of base and precious metals. The amount of precious metals like Ag and Au was also found in higher ranges in large-sized MPCB fractions, which elucidated fact to be considered in the pre-treatment process for metal recoveries. The high content of base and precious metals in waste mobile phones displayed their economic potential in the market. This new source may compensate for the escalating global demand for gold and silver. Results from the study indicated that MPCBs can serve as an excellent secondary source for various metals and as an efficient alternative fuel.

Gold, Silver and Iron in Iron Oxy-hydroxide Precipitate Formed in Process of Acid Mine Drainage

Oxidation of sulfide-containing ores is the main cause of Acid Mine Drainage (AMD), which is an environmental problem associated with both the abandoned and active mines. Iron-bearing sulfide minerals can be oxidized and form mine waters with high sulfate content, low pH, high electrical conductivity, high redox potential, and high concentrations of iron, aluminum, and other heavy metals. In the process of AMD, precipitation of poorly crystalized oxy-hydroxides of iron with a large active surface can occur. On the surface of iron oxy-hydroxide, the precipitated particulate matter, anions, and cations (metals) could be adsorbed. Mine waters can contain a certain amount of precious metals that can also be adsorbed onto an iron particulate matter surface, which is investigated in this research work. In this work, the samples of iron oxy-hydroxide particulate matter at abandoned gold mine waste in Bakovici (Central Bosnia and Herzegovina) are used. Several parameters including pH, water content, particle size distribution, sulfate content, electrical conductivity, redox potential, and amounts of gold, silver, and iron are measured on the selected mine waste samples. The results obtained indicate that significant amounts of gold (average: 6.8 mg/kg) and silver (average: 7.13 mg/kg) are present in the iron precipitate. Adsorption of precious metals onto the iron oxy-hydroxide surface is strongly pH-dependent. At a very low pH value, desorption of precious metals is favorite. Thus, precious metals are only partially adsorbed onto the iron oxy-hydroxide surface.

Modification of Commercial Pt/C Catalyst with Graphene Nanoplatelets for Sensitive and Selective Detection of Acetaminophen in Commercial Tablets

Here, commercial Pt/C catalyst was modified with graphene nanoplatelets (GNPs) to construct electrochemical acetaminophen (APAP) sensors with high sensitivity and wide linear range. Physical mixture of Pt/C and GNPs with various contents were used to prepare ink formulations for the construction of electrochemical APAP sensors. The carbon content was kept constant to show the effect of GNPs content in the catalyst layer while decreasing the total Pt loading on the electrode surface. The Pt/C and GNPs were characterized using XRD, TEM, XPS, SEM, and EDS techniques. The analytical results indicated that the performance of the sensors was improved after GNPs introduction in Pt/C catalyst. It is of the note that while the amount of precious metal, Pt, on the electrode surface was decreased, the overall sensor performance was enhanced, confirming the importance of the catalyst support on the electrochemical performance of the catalyst systems. The sensors displayed a wide range of 0.1–3.0 mM with a high sensitivity of 209.07 μA. mM−1. cm−2. The reliability of the constructed sensors was evaluated by the determination of APAP concentration in commercial tablets and excellent recovery values were achieved.

Development of New Electrocatalytic Nanomaterials for the Oxidation of Ammonia As Anodic Materials in a Direct Ammonia Fuel Cell

Fuel cells are electrochemical devices that directly convert chemical energy to electrical energy. A common justification for using fuel cells has been environmental protection, as fuel cells produce only water as combustion by-product and thus they are “zero emission” devices [1]. The most widely deployed fuel cell is PEMFC, which uses hydrogen as fuel. However, fuel distribution and fuel tank fill-up, associated with the physical state of the fuel, a highly compressed gas, is problematic. In order to achieve the effective energy content of a gasoline tank, an H2 pressure of 700 bar is required in FCV's storage tanks. An alternative approach to avoid using compressed hydrogen, is to use liquid hydrogen-rich fuels such as methanol, ethanol or ammonia, which are liquid in conditions close to the atmosphere. Being liquid fuels, they are easy to transport and store, which reduces transport and infrastructure costs. In addition, it allows by minor modifications, to take advantage of the current infrastructure and facilities that are normally used for conventional fuels.Recently hydrogen carriers have attracted much attention as alternative fuels to hydrogen for the realization of a low-carbon society. The search for a clean, economical and sustainable fuel with high energy density has led to the increasing consideration of nitrogen-based fuels, such as ammonia and hydrazine, as a promising alternative reactant to use in fuel cells. Ammonia has certain advantages over other N2-compounds. It is extensively used in the agricultural, plastics and explosives industries. In addition, ammonia is produced on an industrial scale by the well-known Haber-Bosch method. There are many other advantages to consider ammonia, as a promising candidate among them liquefaction under mild conditions (−33.4 °C at atmospheric pressure or 8.46 atm at 20 °C), high volumetric energy density, low production cost, and being a carbon-free fuel. In response to these technical trends, the development of energy conversion devices utilizing ammonia fuel such as fuel cells and gas turbine generators has now accelerated [2].Electrochemical oxidation of ammonia attracted great attention for wastewater treatment, as well as its application in direct ammonia fuel cells and hydrogen production in energy conversion technologies. However, ammonia electro-oxidation to produce H2 and N2 is a slow process and efficient electrocatalysts are required [3]. Several studies have been devoted to the development of efficient electrocatalysts for ammonia oxidation in alkaline solutions. Platinum is the most active catalyst for this process, however it is expensive and easily become inactive by nitrogen adsorption. Various mono- and bimetallic catalysts have been investigated [4]. In order to make ammonia FCs commercially attractive, the amount of precious metals needs to be reduced. This can be achieved by using electrocatalysts as nanoparticles dispersed on high surface area conductive supports, e.g., carbon black. In this work carbon-supported bimetallic, PtM, as well as trimetallic PtMRu (M = Co, Cu, Ru, Ni) catalysts were synthesized using a modified impregnation method [5]. These synthesized materials have been studied as potential catalysts for ammonia electro-oxidation. All materials were characterized physic chemically by techniques such as TEM, SEM, EDS and XPS. in order to determine the size and distribution of the nanoparticles on the conductive support and the chemical composition and oxidation state of the constituent elements of the catalyst. Techniques such as CV, CA and EIS were used for electrochemical characterization. All electrochemical measurements were carried out in a three-electrode PTFE homemade cell. A large surface area gauze-Pt and a Ag/AgCl electrode were used as the counter electrode and the reference electrode, respectively. As working electrode a glassy carbon with a thin catalyst layer was used. The behaviour of the new materials towards ammonia electrooxidation was evaluated. 1 M KOH was used as the supporting electrolyte, to which increasing amounts of NH4OH were added. The catalysts synthesized in this work have shown to be very attractive as active materials for the anode of a direct ammonia fuel cell. The addition of co-catalysts to the Pt has improved its electrocatalytic behavior towards ammonia electro-oxidation. [1] Frontiers of Engineering: Reports on Leading-Edge Engineering from the 2005 Symposium. (2006). Washington, D.C.: National Academies Press. [2] Matsui, T., Suzuki, S., Katayama, Y., Yamauchi, K., Okanishi, T., Muroyama, H., & Eguchi, K. (2015). Langmuir, 31(42), 11717–11723. [3] Siddiqui, O., & Dincer, I. (2018). Thermal Science and Engineering Progress, 5, 568-578. [4] Lomocso, T. L., & Baranova, E. A. (2011). Electrochimica Acta, 56(24), 8551–8558. [5] Asteazaran, M., Cespedes, G., Moreno, M. S., Bengió, S., & Castro Luna, A. M. (2015). International Journal of Hydrogen Energy, 40(42), 14632–14639.

Commodity and Token Monies

A government defines a dollar as a list of quantities of one or more precious metals. If issued in limited amounts, token money is a perfect substitute for precious metal money. Atemporal equilibrium conditions determine how quantities of precious metals and token monies affect an equilibrium price level. Within limits, a government can peg the relative price of two precious metals, confirming Fisher's (1911) response to a classic criticism of bimetallism. Monometallism dominates bimetallism according to a natural welfare criterion.

Design of efficient Pt-based electrocatalysts through characterization by X-ray absorption spectroscopy

A method is described to determine the internal structure of electrocatalyst nanoparticles by in situ X-ray absorption spectroscopy (XAS). The nondestructive spectroscopic technique typically utilizing synchrotron radiation as the source measures changes in the X-ray absorption coefficient as a function of energy. The bulk technique has found its use for materials characterization in all scientific areas, including nanomaterials. The analysis of the internal structure of nanoparticles reveals interatomic distances and coordination numbers for each element, and their values and mutual relations indicate whether the elements form a homogeneous or heterogeneous mixture. The core-shell heterogeneous structure in which certain elements are predominantly located in the core, and others form the encapsulating shell is of particular importance in catalysis and electrocatalysis because it may reduce the amount of precious metals in nanoparticles by replacing the atoms in the core of nanoparticles with more abundant and cheaper alternatives. The examples of nanoparticle structures designed in the laboratory and the approach to model efficient catalysts through systematic analysis of XAS data in electrochemical systems consisting of two and three metals are also demonstrated.

Incorporation of Platinum and Gold Partially Reduced Graphene Oxide into Polymer Electrolyte Membrane Fuel Cells for Increased Output Power and Carbon Monoxide Tolerance

The Polymer Electrolyte Membrane Fuel Cells (PEMFCs) platinum catalyst’s susceptibility to poisoning by carbon monoxide (CO) reduces its output power. In an effort to diminish poisoning, gold and platinum nanoparticles were incorporated onto partially reduced graphene oxide (Au/Pt-prGO) sheets to reduce both nanoparticle aggregation and the amount of precious metal needed. Applying this material onto the electrodes and Nafion membrane of a PEMFC was hypothesized to increase CO tolerance as well as power output. Aliquots of graphene oxide (GO) were functionalized with platinum and/or gold nanoparticles using a simple desktop synthesis at room temperature. Partial reduction with NaBH4 maintained hydrophilic solubility. Test solutions applied to electrodes and to electrodes + Nafion membrane were first tested in a PEM fuel cell with a pure H2 gas feed and then repeated with a H2 gas feed containing 1000 ppm of CO. Test arrangements averaged doubling the output power of the poisoned control, with the most effective yielding an output power ∼250% that of the poisoned control. Additionally, each system’s poisoned output power (PP) was compared to its highest possible output power (PM), with the most effective setup showing no reduction in output power, even with a H2 gas feed containing 1000 ppm of CO. Thus, this offers promise of a simple, cost-effective method of both improving PEMFC power output while reducing or even eliminating CO poisoning at room temperature.

Simulation and Experimental Study of Thermal Effects on Composite Contacts in Electrical Life Cycle Tests of DC Relays

Composite contacts used for dc relays can help reduce their cost and the amount of precious metals used in their construction. Because of their electrical properties, silver metal oxide-copper (AgMeO-Cu) composite contacts are widely used; however, at heavy loads, the bonding strength of the composite contact will change due to the influence of uneven temperature and stress distributions, which may even cause failure in the form of oxide layer peeling. Here, typical AgSnO2In2O3-Cu composite contacts are studied. A 3-D finite-element simulation model that considers contact making, arcing, and breaking was established to calculate the contact temperature and thermal stress after any operation cycle. The model can be used to determine the variation of the contact temperature and thermal stress distributions versus operation time during an electrical life cycle test. For different AgMeO layer thicknesses (0.25 and 0.38 mm), the temperature and thermal stress distribution of composite contact's bonding area were calculated under different current load levels: 30, 45, and 60 A, while the load voltage is a constant 17 V. Results show that the thickness of the AgMeO layer has a significant effect on the temperature and stress distribution of the bonding area in the moveable contact and the composite contacts may more easily curl and crack with an increment of the AgMeO layer thickness under the same current condition. The simulation results agree well with the experimental data and the relative error is less than 10%. The validity of the model and method was verified. The numerical model in the paper may be used to analyze a composite contact's properties and is therefore useful for design optimization and the selection of composite contact materials.

Electrochemical Oxidation of the Carbon Support to Synthesize Pt(Cu) and Pt-Ru(Cu) Core-Shell Electrocatalysts for Low-Temperature Fuel Cells

The synthesis of core-shell Pt(Cu) and Pt-Ru(Cu) electrocatalysts allows for a reduction in the amount of precious metal and, as was previously shown, a better CO oxidation performance can be achieved when compared to the nanoparticulated Pt and Pt-Ru ones. In this paper, the carbon black used as the support was previously submitted to electrochemical oxidation and characterized by XPS. The new catalysts thus prepared were characterized by HRTEM, FFT, EDX, and electrochemical techniques. Cu nanoparticles were generated by electrodeposition and were further transformed into Pt(Cu) and Pt-Ru(Cu) core-shell nanoparticles by successive galvanic exchange with Pt and spontaneous deposition of Ru species, the smallest ones being 3.3 nm in mean size. The onset potential for CO oxidation was as good as that obtained for the untreated carbon, with CO stripping peak potentials about 0.1 and 0.2 V more negative than those corresponding to Pt/C and Ru-decorated Pt/C, respectively. Carbon oxidation yielded an additional improvement in the catalyst performance, because the ECSA values for hydrogen adsorption/desorption were much higher than those obtained for the non-oxidized carbon. This suggested a higher accessibility of the Pt sites in spite of having the same nanoparticle structure and mean size.

A New Class of Electrocatalysts for Hydrogen Production from Water Electrolysis: Metal Monolayers Supported on Low-Cost Transition Metal Carbides

This work explores the opportunity to substantially reduce the cost of hydrogen evolution reaction (HER) catalysts by supporting monolayer (ML) amounts of precious metals on transition metal carbide substrates. The metal component includes platinum (Pt), palladium (Pd), and gold (Au); the low-cost carbide substrate includes tungsten carbides (WC and W(2)C) and molybdenum carbide (Mo(2)C). As a platform for these studies, single-phase carbide thin films with well-characterized surfaces have been synthesized, allowing for a direct comparison of the intrinsic HER activity of bare and Pt-modified carbide surfaces. It is found that WC and W(2)C are both excellent cathode support materials for ML Pt, exhibiting HER activities that are comparable to bulk Pt while displaying stable HER activity during chronopotentiometric HER measurements. The findings of excellent stability and HER activity of the ML Pt-WC and Pt-W(2)C surfaces may be explained by the similar bulk electronic properties of tungsten carbides to Pt, as is supported by density functional theory calculations. These results are further extended to other metal overlayers (Pd and Au) and supports (Mo(2)C), which demonstrate that the metal ML-supported transition metal carbide surfaces exhibit HER activity that is consistent with the well-known volcano relationship between activity and hydrogen binding energy. This work highlights the potential of using carbide materials to reduce the costs of hydrogen production from water electrolysis by serving as stable, low-cost supports for ML amounts of precious metals.

Investigation of the Influence of Hydrocyclone Geometric and Flow Parameters on Its Performance Using CFD

Effectiveness and efficiency of hydro-cyclone separators are highly dependent on their geometrical parameters and flow characteristics. Performance of the hydro-cyclone can, therefore, be improved by modifying the geometrical parameters or flow characteristics. The mining and chemical industries are faced with problems of separating ore-rich stones from the nonore-rich stones. Due to this problem a certain amount of precious metals is lost to the dumping sites. Plant managers try to solve these problems by stockpiling what could be useless stones, so that they can be reprocessed in the future. Reprocessing is not a sustainable approach, because the reprocessed material would give lower yield as compared to the production costs. Particulate separation in a hydro-cyclone has been investigated in this paper, by using computational fluid dynamics. The paper investigated the influence of various flow and geometric parameters on particulate separation. Optimal parameters for efficient separation have been determined for the density of fluid, diameter of the spigot, and diameter of the vortex finder. The principal contribution of this paper is that key parameters for design optimization of the hydro-cyclone have been investigated.

Industrial biotemplating saves precious metals in catalysts

Modern molecular biology provides the tools to design surfaces on the nanometer scale. This opens the way to a breakthrough innovation, which can optimize many industrial processes. In a proof-of-concept study, scientists were able to successfully reduce the amount of precious metals required for a diesel oxidation catalyst. This was the first successful application, and right now the biotemplating technology awaits further development for other applications involving catalytic processes or specifically designed surfaces for industrial processes.

Plasma Synthesis: A Novel Way of Making Catalysts

AbstractIn the present paper a novel method of manufacturing mobile emission control catalysts (MECC) is presented. The manufacturing of these novel catalysts consists of three steps: In a first processing step micron sized powders consisting of an oxide powder, typically Al2O3 or SiO2 or the like, and micron sized precious metal powders, Pt, Pd, Rh or the like, are co-fed into a DC plasma gun. Inside the gun the powders are vaporized at temperatures of approximately 25,000 K. After the powders are vaporized the vapor is rapidly quenched at rates of approximately 1,000,000 K/s. This process step yields so-called Nano on Nano Catalysts™, where nano clusters of precious metals atoms are condensed onto the nano sized oxide particles. In a second processing step these Nano on Nano Catalysts™ are dispersed in water. This step is followed by a third, and final processing step, where the Nano on Nano Catalysts™ are integrated onto the final support, i.e. the monoliths (or honeycombs), which ultimately are canned and located downstream of a vehicle’s engine. Catalysts manufactured under the above conditions are then tested against reference catalysts, both under fresh and aged conditions. Test results show that the plasma based catalysts have better light off temperatures after aging than the reference catalysts if they contain the same amount of precious metals as the reference catalyst. If the precious metal amount for the plasma based catalysts is reduced to approx. half the amount of the reference catalysts then both catalysts show approx. the same light off temperatures after aging. Above results show that with catalysts based on plasma technology one can either lower the light off temperatures while maintaining the precious metal content compared to reference catalysts, or match the performance of the reference catalysts while reducing the precious metal content to approx. 50%, compared to the reference catalysts.

Heavy and light money in the Netherlands Indies and the Dutch Republic: dilemmas of monetary management with unit of account systems

AbstractIn its Asian operations the Dutch United East Indies Company (VOC) (1602–1798) acted both as a territorial ruler and as a trading company. The company shipped large amounts of precious metals to Asia, both in the form of bullion and as coins, to pay for its trade and to provide currency for the areas under its control. The Company faced the problem that silver coins rapidly disappeared from circulation, as demand for silver was high in Asia. The Company attempted to manage the problem with a monetary policy using a unit of account, modelled after the policy of the Dutch Republic. It turned out that the two purposes of the money of account system, viz., putting the bookkeeping on a systematic basis and managing the currency in circulation, were conflicting. The first demanded a fixed unit of account, the second demanded a flexible policy of linking and de-linking the unit of account to real coins. Although the Company managed to muddle through this dilemma, it only succeeded in finding temporary solutions.

Extrusion Forming of Cordierite Honeycomb with Hexagonal Open Cells

Cordierite honeycomb with hexagonal shaped open channels was formed by extrusion forming technique using specially designed mould for the raw oxide mixture of talc, kaolin, alumina and aluminum hydroxide. The honeycomb showed extremely thin wall thickness of 0.15 mm and low coefficient of thermal expansion (CTE) for the high number of cells per square inch (cpsi) approaching to 600. The extruded honeycomb was sintered at various conditions and characterized by XRF, TGA-DTA, XRD, TMA and SEM techniques. The indialite crystalline showing the coefficient of thermal expansion of 1.9 × 10-6/°C was formed while sintering at 1,450°C for 5 h. The influence of Fe2O3 additive and heating condition on the CTE of cordierite was analyzed in details. This particular cordierite honeycomb with high numbers of hexagonal shaped open cells showed a distinct advantage of saving the amount of precious metal catalyst materials to be coated on the substrate in comparison with the honeycomb with rectangular cells while improving the degree of catalyst efficiency when applying the substrate of automotive catalytic converter.

Alchemy and Surface Treatments in Antiquity

Ancient artisans were able to confer special colourings to their artefacts by applying particular techniques and treatments, which were lost in later centuries. They were also able to give copper based alloys the appearance of precious metals. Some of these special methods have been discovered and identified on ancient objects. The most famous of these alloys in Roman times was certainly Corinthian bronze, a copper alloy containing small amounts of precious metals, which acquired a purple-black or blue-black patination after a chemical bath. Several ancient texts, in particular Pliny and the alchemists, mention this precious material and give information on how it was produced. However, besides Corinthian bronze there were also other patinated alloys, which imitated the more precious version, and other colouring techniques, which could be achieved in different ways. The present paper reports on the author’s latest research on special alloys in antiquity; several ancient examples of coloured metals and alloys are identified by scientific methods (ICP, AAS, XRD, SEM/EDX), and the problem of recognising the various surface treatments on archaeological objects is discussed.