Janssen 1 Plasticizers

Yang X, van Duren JKJ, Janssen RAJ, Michels MAJ, Loos J (2004) Morphology and thermal stability of the active layer in poly(p-phenylenevinylene)/methanofullerene plastic photovoltaic devices. Macromolecules 37 2151... 

MZ AI3-50033 CCRIS 2459 EINECS 211-765-7 Imidazole, 2-methyl- IH-lmidazole, 2-methyl- 2-Methylimidazole NSC 21394. Dyeing auxiliary for acrylic fibers, plastic foams. Crystals mp = 144° bp = 267 very soluble in H2O, EtOH LD50 (mus ori) = 1400 mg/kg. Allchem Ind. BASF Corp. Janssen CNmica. 

Dihydroxyphosphine oxide EINECS 237-066-7 Orthophosphorus Kid Phosphonic acid Phosphorous acid Phosphorus trihydroxide Trihydroxyphosphlne. Interm iate for manu ture of diphosphonic acids and phosphite salts used as pesticides, chelates, and plastic additives restricts color formation in esterification and condensation reactions (In small quantities) chemical reducing agent. Usually marketed as a 20% aqueous solution. White solid mp = 73° dj 1.65 soluble in H2O, EtOH. Albright Wilson Americas Inc. Asira Hassle AB CK Witco Corp. Janssen Chimica Lonzagroup Rasa. 

Octanedicarboxylic acid Sebacic xid Sebacinsaeure Sebacinsaure USAF HC-1. Stabilizer raw material in manufacture of alkyd resins, maleic and other polyesters, plasticizers, polyester rubbers, synthetic polyamide fibers. Leaflets mp = 130.8 bpioo = 295 , bpio = 232 d O = 1.2706 soluble in EtOH, EtzO, slightly soluble in H2O (0.1 g/100 ml), insoluble in CeHe. Janssen Chimica Penta Mfg.i Union Camp. 

AI3-25276 Bis(2-carboxyethyl) sulfide CCRIS 3288 Diethyl sulfide 2,2 -dicarboxylic acid EINECS 203-841-3 HSDB 858 Kyselina (3,p -thiodipropionova Kyselina 3,3-thiodipropionova NSC 8166 Propanoic acid, 3,3 -thiobis- Propionic acid, 3,3 -thiodi- Sulfide, bis(2-carboxyethyl) TDPA 4-Thiaheptanedioic acid Thia-hydracrylic acid 3,3 -thiobis(propanoic acid) 3,3 -Thio-dipropionic acid Thiodihydraciylic acid Thiodiptopion-ic acid Tyox A. Used as an antioxidant in food packaging, soaps, plasticizers, lubricants, fats, and oils. Crystalline white powder mp = 129" soluble in H2O (37 g/l), very soluble in EfOH, Me2CO. CK Witco Corp. Evans Chametics Janssen Chimica. 

Brahec, C.J., F. Padinger, J.C. Hummelen, RjV.J. Janssen, and N.S. Sariciftci. 1999. Realization of large area flexible fuUerene-conjugated polymer photocells A route to plastic solar cells. Synth Met 102 861. 

HuUeman S.H.D., Janssen F.H.P., Fell H., The role of water during plasticization of native stttfches. Polymer, 39, 1998, 2043-2048. 

Since wind barriers are located at the cold side of the thermal insulation (in cold climates) they should combine a sufficient air and water tightness with a high vapour permeance. Materials which combine these properties and are often recommended as wind barriers are the spunbonded plastic films (also called house-wraps). These films are composed of rolled synthetic filaments (typically polypropylene or polyethylene fibres) that are welded together to form a continuous porous fabric. Measuring procedures and results of vapour transfer properties of spunbonded plastic films are reported in detail by Janssens and Hens [36]. The diffusion thicknesses of the films are a few centimetres and of the same order of magnitude as an air boundary layer. 

J Janssen. Nucleating agents for partially crystalline polymers. In R Gachter, H Muller, eds. Plastics Additives Handbook, 3rd edn., Munich Hanser, 1990, p 862. 

The OSL model was constructed in order to explain curious observations reporting that the maximum pressure P in a sandpile was not necessarily directly below the pile s peak but, rather, could occur on a ring of nonzero radius [49-52] (see also Savage [53]). In some cases, the pressure at the base was actually reported to have a local minimum under the peak, the so-called stress dip phenomenon. The 2D OSL model has a Janssen-like constitutive relation of the form (Jxx = ( zz + where z is the vertical and x is the horizontal direction. When coupled with the constraint of stress balance, this leads to the proposal that (static) stresses within a granular material satisfy a hyperbolic PDF in the spatial variables, x and z. Bouchaud et al. then showed that this model could predict a stress dip. Savage [53] argued that soil mechanics models [14] can also account for a stress dip. Elasto-plastic soil mechanics models [ 14] are elastic below yield and are described in this case by elliptic equations (above yield, they are characterized by hyperbolic equations). Hence, the OSL and soil mechanics approaches are inherently different types of models. 

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