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Palladium chemical properties

Physical and Mechanical Properties. Whereas there are some similarities in the physical and chemical properties between corresponding members of the PGM triads, eg, platinum and palladium, the PGMs taken as a unit exhibit a wide range of properties (2). Some of the most important are summarized in Table 2. [Pg.163]

Whereas the utility of these methods has been amply documented, they are limited in the structures they can provide because of their dependence on the diazoacetate functionality and its unique chemical properties. Transfer of a simple, unsubstituted methylene would allow access to a more general subset of chiral cyclopropanes. However, attempts to utilize simple diazo compounds, such as diazomethane, have never approached the high selectivities observed with the related diazoacetates (Scheme 3.2) [4]. Traditional strategies involving rhodium [3a,c], copper [ 3b, 5] and palladium have yet to provide a solution to this synthetic problem. The most promising results to date involve the use of zinc carbenoids albeit with selectivities less than those obtained using the diazoacetates. [Pg.86]

Beside these catalytically active metallophosphine dendrimers (see above), preliminary studies on the chemical properties of phoshorus-based dendrimers complexed to metals such as platinum, palladium and rhodium have been described by Majoral, Caminade and Chaudret [21], They showed that these macromolecules (see Scheme 13) could be useful for the (in situ) generation of metallodendrimer catalysts. [Pg.496]

The discovery in the early 1980s that cationic palladium-phosphine complexes catalyse the copolymerisation of carbon monoxide with ethene or a higher a-olcfin to yield perfectly alternating polyketones has since attracted continuous increasing interest [1,2]. This is because the monomers are produced in large amounts at a low cost and because polyketones represent a new class of thermoplastics of physical-mechanical and chemical properties that have wide applications [3-6]. In addition, easy functionalisation can open the way to a large number of new materials [7]. The copolymerisation has... [Pg.133]

Platinum metah—includes unreactive transition elements located in groups 8, 9, and 10 of periods 5 and 6. They have similar chemical properties. They are ruthenium, rhodium, palladium, osmium, iridium, and platinum. [Pg.37]

Platinum is the main metal in the platinum group, which consists of metals in both period 5 and period 6. They are ruthenium (Ru), rhodium (Ro), and palladium (Pd) in period 5 and osmium (Os), iridium (Ir), and platinum (Pt) in period 6. All six of these metals share some of the same physical and chemical properties. Also, the other metals in the group are usually found in platinum ore deposits. [Pg.163]

Metal ion modified polyimide films have been prepared to obtain materials having mechanical, electrical, optical, adhesive, and surface chemical properties different from nonmodified polyimide films. For example, the tensile modulus of metal ion modified polyimide films was increased (both at room temperature and 200 0 whereas elongation was reduced compared with the nonmodif ied polyimide (i). Although certain polyimides are )cnown to be excellent adhesives 2) lap shear strength (between titanium adherends) at elevated temperature (275 0 was increased by incorporation of tris(acetylacetonato)aluminum(III) (2). Highly conductive, reflective polyimide films containing a palladium metal surface were prepared and characterized ( ). The thermal stability of these films was reduced about 200 C, but they were useful as novel metal-filled electrodes ( ). [Pg.395]

Trace impurities in noble metal nanoclusters, used for the fabrication of highly oriented arrays on crystalline bacterial surface layers on a substrate for future nanoelectronic applications, can influence the material properties.25 Reliable and sensitive analytical methods are required for fast multi-element determination of trace contaminants in small amounts of high purity platinum or palladium nanoclusters, because the physical, electrical and chemical properties of nanoelectronic arrays (thin layered systems or bulk) can be influenced by impurities due to contamination during device production25 The results of impurities in platinum or palladium nanoclusters measured directly by LA-ICP-MS are compared in Figure 9.5. As a quantification procedure, the isotope dilution technique in solution based calibration was developed as discussed in Chapter 6. [Pg.265]

Chemical Properties.—Both chlorine and fluorine attack palladium at high temperatures, yielding the respective halogenides. Chlorine water attacks it slowly, and an alcoholic solution of iodine effects the formation of a superficial layer of palladous iodide. Iodine vapour tarnishes the metal, yielding the iodide, whilst gently heating iodine and finely divided palladium causes them to unite more or less imperfectly. [Pg.182]

Occurrence and History of Palladium—Preparation—Physical Varieties Physioal Properties—Permeability to Hydrogen--Occlusion of Canos Occlusion of Hydrogen—Chemical Properties--Catalytic Activity Crystalline Palladium—Colloidal Palladium—Spongy Palladium —Palladium Black —Uses—Atomic Weight—Alloys. [Pg.378]

Osmium is an element in Group 8 (VIIIB) of the periodic table. The periodic table is a chart showing how chemical elements are related to one another. Osmium is also a member of the platinum family. This family consists of five other elements ruthenium, rhodium, palladium, iridium, and platinum. These elements often occur together in Earth s cmst. They also have similar physical and chemical properties, and they are used in alloys. [Pg.401]

Electronic and chemical properties of palladium in bimetallic systems How much do we know about heteronuclear metal-metal bonding ... [Pg.438]

In this chapter, an overview is presented of studies that deal with the electronic and chemical properties of Pd in bimetallic systems. We will focus on palladium for three main reasons. First, bimetallic catalysts that contain Pd or other Group-10 metals have many uses isomerization of hydrocarbons, olefin hydrogenation, CO oxidation, alcohol synthesis, acetylene trimerization, etc. [8,10,19-21]. Second, palladium is very sensitive to the formation of bimetallic bonds [22-24]. And third, there is a vast number of experimental and theoretical articles in the literature that examine the properties of Pd in bimetallic systems [14,15,19-23,25-44]. From this large volume of work, one can get a general idea of how deep is our knowledge about the basic nature of bimetallic bonding and how it affects the properties of a metal. [Pg.439]

Butanediyl)(TV, TV, TV, TV -tetramethyl-l, 2-ethanediamine)palladium(II) is a white crystalline solid, highly hygroscopic and air-sensitive, readily losing tmeda. It must be handled and stored under argon. It is moderately soluble in pentane and very soluble in benzene. The H-NMR spectrum (60 MHz,benzene-rf6,5 in ppm downfield from TMS) must be recorded immediately after the preparation of the sample, at temperatures lower than 10°. It shows a broad multiplet ranging from 0.9-1.6 (methylene protons of the palladacyclopentane moiety), and resonances at 2.2-2.3 (methyl and methylene protons of tmeda). Other chemical properties are given in the literature.3... [Pg.169]

M—C a bonds are very few. In this chapter more precisely, larger metallomacrocycles with at least one M—C a bond with or without additional heteroatoms are reviewed. Unlike in other chapters, here the compounds are reviewed on the basis of the metal atom that is present in the ring, since the generalization of the synthesis, structure elucidation, and physical and chemical properties of all titled metallomacrocycles is rather intricate. Hence the chapter is framed to focus on two classes of metallomacrocycles (i) with mercury atoms, and (ii) with platinum and/or palladium atoms. [Pg.1034]

The lanthanide contraction, however, has also effects for the rest of the transition metals in the lower part of the periodic system. The lanthanide contraction is of sufficient magnitude to cause the elements which follow in the third transition series to have sizes very similar to those of the second row of transition elements. Due to this, for instance hafnium (Hf ) has a 4" -ionic radius similar to that of zirconium, leading to similar behavior of these elements. Likewise, the elements Nb and Ta and the elements Mo and W have nearly identical sizes. Ruthenium, rhodium and palladium have similar sizes to osmium iridium and platinum. They also have similar chemical properties and they are difficult to separate. The effect of the lanthanide contraction is noticeable up to platinum (Z = 78), after which it no longer noticeable due to the so-called Inert Pair Effect (Encyclopedia Britannica 2015). The inert pair effect describes the preference of post-transition metals to form ions whose oxidation state is 2 less than the group valence. [Pg.59]

Palladium Compounds Stoichiometric Preparation, In Situ Generation, and Some Physical and Chemical Properties... [Pg.42]

See other pages where Palladium chemical properties is mentioned: [Pg.13]    [Pg.230]    [Pg.656]    [Pg.27]    [Pg.104]    [Pg.89]    [Pg.9]    [Pg.89]    [Pg.67]    [Pg.27]    [Pg.291]    [Pg.16]    [Pg.189]    [Pg.275]    [Pg.107]    [Pg.1051]    [Pg.371]    [Pg.6]    [Pg.442]    [Pg.19]    [Pg.292]    [Pg.128]    [Pg.751]    [Pg.168]    [Pg.299]    [Pg.22]   
See also in sourсe #XX -- [ Pg.6 , Pg.11 ]

See also in sourсe #XX -- [ Pg.435 ]

See also in sourсe #XX -- [ Pg.6 , Pg.11 ]



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Palladium properties

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