Civil Engineering Reference
In-Depth Information
65. I. Dierking ,
Textures of liquid crystals
, Wiley-VCH, Weinheim . ( 2003 ).
66. D. Demus and L. Richter ,
Texture of liquid crystals
, Verlag Chemie , Weinheim. ( 1978 ).
67. H. Sackmann and D. Demus , h e problems of polymorphism in liquid crystals.
Mol. Cryst.
Liq. Cryst
. 21 , 239 - 273 ( 1973 ).
68. J. M. Seddon, Structural studies of liquid crystals by X-ray dif raction , in
Handbook of
crystals, fundamentals
, Vol. 1, Chapter VIII, D. Demus, J. W. Goodby, G. W. Gray, and H.
W. Spiess and V. Vill (Eds.),
pp. 635-671, Wiley VCH, New York
. ( 1998 ).
69. P. Keates and G. R. Mitchell, Local structural correlations in anisotropic aqueous solutions
of hydroxypropyl cellulose.
Polymer
33 , 3298 - 3301 ( 1992 ).
70. Q. Dai, S. A. Khan, and J. F. Kadla, Transient rheological behavior of lyotropic (acetyl)
(ethyl)cellulose/m-cresol solutions.
Cellulose
, 13 , 213 - 223 ( 2006 ).
71. D. Demus , Chemical structure and mesogenic properties , in
Handbook of liquid crystals,
Fundamentals,
Vol. 1, Chapter VI, D. Demus, J. W. Goodby, G. W. Gray, and H. W. Spiess
and V. Vill (Eds.), pp. 133-189, Wiley VCH, New York. (1998).
72. M. Barón , Dei nitions of basic terms relating to low-molar-mass and polymer liquid crys-
tals .
Pure Apll. Chem
. 73 , 845 - 895 ( 2001 ).
73. M. Barón and R. F. T. Stepto, Dei nitions of basic terms relating to polymer liquid crystals.
Pure Apll. Chem
. 74 , 493 - 509 ( 2002 ).
74. D. A. Dunmur ,
Liquid crystals fundamentals, pp. 1-23
, World Scientii c .( 2002 ).
75. P. J. Collings ,
Liquid crystals: Nature's delicate phase of matter
, Second Edition , pp. 18-28 ,
Princeton University Press , New Jersey . ( 2002 ).
76. M. Granström , Cellulose Derivatives : Synthesis, Properties and Applications, Academic
Dissertation , Helsinki, 60- 61 ( 2009 ).
77. D. G. Gray, Chemical characteristics of cellulosic liquid crystals.
Faraday Discuss. Chem.
Soc
. 79 , 257 - 264 ( 1985 ).
78. D. Wenzlik, Liquid Crystalline Cellulose Derivatives for Mirrorless Lasing, Dissertation,
Johannes Gutenberg University Mainz, (2013).
79. J. F. Revol, H. Bradford, J. Giasson, R. H. Marchessault, and D. G. Gray.
Int .
J. Biol.
Macromol
. 14 , 170 - 172 ( 1992 ).
80. K. Fleming, D. G. Gray, and S. Matthews, Cellulose Crystallites.
Chem. Eur . J.
7 , 1831 - 1836
( 2001 ).
81. J. Araki, M. Wada, S. Kuga, and T. Okano, Birefringent Glassy Phase of a Cellulose
Microcrystal Suspension.
Langmuir
16 , 2413 - 2415 ( 2000 ).
82. F. Kimura, T. Kimura, M. Tamura, A. Hirai, M. Ikuno, and F. Horii, Magnetic Alignment of
the Chiral Nematic Phase of a Cellulose Microi bril Suspension.
Langmuir
21 , 2034 - 2037
( 2005 ).
83. L. Quintero, D. E. Clark, J.-L. Salager, and A. Forgiarini, Mesophase l uids with extended
chain surfactans for downhole treatments, US Patent 8 235 120 B2, assigned to Baker
Hughes Incorporated, Houston, TX (US) (August 7, 2012).
84. B. L. Peng, N. Dhar, H. L. Liu, K. C. Tam, Chemistry and applications of nanocrystal-
line cellulose and its derivatives: A nanotechnology perspective.
Can. J. Chem. Eng
. 89 ,
1191 - 1206 ( 2011 ).
85. J. Han, C. Zhou, Y. Wu, F. Liu, and Q. Wu, Self-assembling behavior of cellulose nanopar-
ticles during freeze-drying: Ef ect of suspension concentration, particle size, crystal struc-
ture, and surface charge.
Biomacromolecules
14 , 1529 - 1540 ( 2013 ).
86. Y. Genga, P. Brogueirac, J. L. Figueirinhas, M. H. Godinho, and P. L. Almeida, Light shut-
ters from nanocrystalline cellulose rods in a nematic liquid crystal.
Liq. Cryst
. 40 , 769 - 773
( 2013 ).
