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PLOS ONE 2009

The Structural Dilemma of Bulk Polyethylene: An Intermediary Structure

DOI: 10.1371/journal.pone.0006228

Morteza Laridjani, Pierre Leboucher

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Abstract:

Background The Fourier space (reciprocal space) image of bulk polyethylene consists of lines superimposed on the coherent diffuse background. The mixed character of the image indicates the complex nature of these compounds. The inability in detecting full images of reciprocal space of polymeric substances without Compton radiation and the other undesirable diffuse scatterings has misled the structural analysis (structural characterisation) of these materials. Principal Findings We propose the use of anomalous diffractometry where, it is possible to obtain a real image of reciprocal space without Compton radiation and other undesirable scatterings. By using classical diffractometry techniques this procedure is not possible. This methodology permitted us to obtain the “Direct Delta function”, in the case of polycrystalline substances that was not previously detected. A new procedure was proposed to interpret the image of reciprocal space of bulk polyethylene. The results show the predominance of the geometry of local order determination compared to the crystal unit cell. The analysis of x-ray diffraction images illustrates that the elementary structural unit is a tetrahedron. This structural unit illustrates the atoms in the network scatter in a coherent diffuse manner. Moreover, the interference function derived from the coherent diffuse scattering dampens out quickly and the degree of randomness is superior to a liquid state. The radial distribution function derived from this interference function shows bond shortening in the tetrahedron configuration. It is this particular effect, which stabilises polyethylene. Conclusion Here we show by anomalous diffractometry that the traditional concept of the two-phase or the crystal-defect model is an oversimplification of the complex reality. The exploitation of anomalous diffractometry has illustrated that polyethylene has an intermediate ordered structure.

References

[1]	Mull N (1917)
[2]	Nishikama (1913)
[3]	Scherrer P (1920)
[4]	Bunn CW, Alcock TC (1945) The Texture of Polyethylene. Trans Faraday Soc 41: 317.
[5]	Alexander LE (1969) X-ray diffraction methods in polymer science. Degree of crystallinity in polymer 137.
[6]	Cullity BD (1956) Elements of x-ray diffraction. The Hanwalt Method 1938: 379.
[7]	Ruland W (1961) X-ray determination of crystallinity and diffuse order scattering. Acta cryst 14: 1180.
[8]	Vonk CG (1973) Computerisation of Ruland's x-ray method for determination of the crystallinity in polymers. Journal applied crystal 6: 148.
[9]	Guinier A (1981) Intermediary states between order and disorder in diffraction studies on non-crystalline substances. Elsevier- Editors: Hargitti, I Jorville, W.
[10]	Klug BP, Alexander LE (1974) X-ray diffraction procedure for polycrystalline and amorphous material. pp. 144–148, 793–799, 854–855, 189–196.
[11]	Schuur G (1955) Some aspects of the crystallization of high polymers. Communication. The Netherlands: Rubber-Stiching.
[12]	Statton WO (1967) The meaning of crystallinity when judged by x-rays. J Polymer Sci 18: 33–50.
[13]	Jaccodine R (1955) Observation of spiral growth steps in ethylene polymer. Nature 176: 305.
[14]	Keller A (1957) A note on single crystals in polymers: evidence for folded chain configuration. PhilMag 2: 1171.
[15]	Yoon DY, Flory PG (1977) Small-angel scattering by semicrystalline polyethylene. Polymer 8: 509.
[16]	Laridjani M (1996) A new structure for an old quasi-crystal. JPhys I Fr 6: 1347–1364.
[17]	Laridjani M, Denoyer F (2004) Study of geometrical local order in a non-ideal solid solution: an intermediary structure. J Appl Crystal 37: 716–723.
[18]	Laridjani M, Donnadieu P, Denoyer F (2002) Experimental overview of complex intermetallic structure. Structure Chemistry 113: 385–396.
[19]	Leboucher P (1985) Patent-Licence, ANVAR. Patent-Licence, ANVAR:.
[20]	Laridjani M, Leboucher P, Sadoc JF (1998) Un diffractometre polyvalent, pour l'etude des poudres avec le rayonment synchrotron. Spectra 16: 128.
[21]	Champetier G, Monnerie L (1969) pp. 403–418, 431, 583. Introduction a la chimie macromoleculaire Eds Masson et Cie, Paris.
[22]	Bunn CW (1939) The crystal structure of long-chain normal paraffin hydrocarbons. The shape of the >CH2 group. Trans Farady Soc 35: 482.
[23]	Bridley GW (1961) The x-ray identification and crystl structure of clay minerals
[24]	Wolff PM de (1957) Determination of unit cell parameters. Acta Crystal 10: 590–595.
[25]	Laridjani M, Epstein A (1999) Edge of disorder- Analysis of disordered polymers: Polyaniline. European Physical Journal B - Condensed Matter and Complex Systems 585–597.
[26]	Gander W, Hrehicer J (1992) Solving problems in scientific computing using Maple and Metlab. Berlin Springer.
[27]	Guinier A (1952) X-ray crystallographic technology. London: Hilgers and Watts. pp. 231–237.
[28]	Guinier A, Dexter DL (1963) X-ray studies of materials John Wiley. 71.
[29]	Kaplow R, Strong SL, Averbach BL (1965) Radial Density function for liquid Mercury and Lead. Phys Rev 138:
[30]	Laridjani M, Sadoc JF (1989) Relationship between polytetrahedral crystals and glasses by using anomolous diffraction techniques and geometrical modelling. J Phys France 50: 1953–1966.
[31]	Laridjani M, Sadoc JF, Raoux D (1987) Structure of the amorphous Cu5Y:Anomalous x –ray diffraction and modelling. J Non-Cryst Solids 91: 217–234.
[32]	Muller A (1928) A further x-ray investigation of long chain compunds (n-hydrocarbon). Proc Roy Soc A 120: 437.
[33]	Holmes DR, Miller RG, Palmer RP, Bunn CW (1953) Crossed amorphous and crystalline chain orientation in polythene film. Nature 171: 1104–1106.
[34]	Walter ER (1956) Reading Polymer Sci 21: 561.
[35]	Tsuneo S, Tetsuhiko H, Kenzo T (1968) Phase transformation and deformation processes in oriented polyethylene. Japanese Journal of applied Physics 7: 31.
[36]	Narten AH (1989) Radial distribution of carbon atoms in crystalline and molten polyethylene from x-ray diffraction. J Chem Phys 90: 5857.
[37]	Eyring H (1932) The resultant electric moment of complex molecules. Phys Rev 39: 746.
[38]	Flory PG (1956) Principle of polymer chemistry. Cornell University Press.
[39]	Flory PG (1980) Statistical mechanics of chain molecules. pp. 10–18. Interscience New York.
[40]	Turnbull D (1964) Thermodynamics and kinetics of formation of the glass state and the initial vitrification. Physics of non-crystalline solids 41:
[41]	Hume-Rothery W, Coles BR (1954) The transition metal and their alloys. Advances in Physics 3: 149–243.
[42]	Lebo M, Grant NJ (1974) Structure and properties of splat cooled 2024 Al alloy. Metal trans 5: 1547–1555.
[43]	Hosemann R, Bagchi SN (1962) Direct analysis of diffraction by matters
[44]	Bernal JD (1964) The structure of liquids. Proc R Soc A 284–299.
[45]	Finny JL (1970) Random packings and the structure of simple liquids I. The geometry of random close packing. Proc R Soc A 319: 479–493.

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