Access the full text.
Sign up today, get DeepDyve free for 14 days.
Cellulose, 12
J. Bheda, J. Fellers, James White (1980)
Phase behavior and structure of liquid crystalline solutions of cellulose derivativesColloid and Polymer Science, 258
Masashi Fukawa, Akane Kawaguchi, Kenichiro Hayata, R. Aoki, Mami Furukawa, S. Furumi (2019)
Syntheses and Properties of Cellulosic Derivatives for Reflection Color FilmsJournal of Photopolymer Science and Technology
A. Basta, V. Lotfy, A. Salem (2021)
Impact of some mineral-based nanoparticles versus carbon nanoallotropes on properties of liquid crystal hydroxypropyl cellulose nanocomposite filmsPigment & Resin Technology
A. Basta, A. Girgis, H. El-saied, Mohamed Mohamed (2011)
Synthesis of fluorescence active pyridinedicarbonitriles and studying their application in functional paperMaterials Letters, 65
A. Basta, V. Lotfy, Camilia Eldewany (2021)
Comparison of Copper-crosslinked Carboxymethyl Cellulose Versus Biopolymer-based Hydrogels for Controlled Release of FertilizerPolymer-Plastics Technology and Materials, 60
Kenichiro Hayata, S. Tatsuya, Masashi Fukawa, S. Furumi (2019)
Thermotropic Cholesteric Liquid Crystals from Cellulose Derivatives with Ester and Carbamate GroupsJournal of Photopolymer Science and Technology
S. Tseng, G. Laivins, D. Gray (1982)
The propanoate ester of (2-hydroxypropyl)cellulose: a thermotropic cholesteric polymer that reflects visible light at ambient temperaturesMacromolecules, 15
Ryota Chiba, Y. Nishio, Yuka Sato, M. Ohtaki, Yoshiharu Miyashita (2006)
Preparation of cholesteric (hydroxypropyl)cellulose/polymer networks and ion-mediated control of their optical properties.Biomacromolecules, 7 11
Xi Chen, Nan Zheng, Qiao Wang, Lingzhi Liu, Y. Men (2017)
Side-chain crystallization in alkyl-substituted cellulose esters and hydroxypropyl cellulose esters.Carbohydrate polymers, 162
D. Lavanya, M. Dixit, Prudhvi Raavi, V. Krishna (2011)
SOURCES OF CELLULOSE AND THEIR APPLICATIONS - A REVIEW
V. Lotfy, Safaa Hassan, Perihan Khalf‐Alla, A. Basta (2020)
The role of side chain of amino acid on performance of their conjugates with carboxymethyl cellulose and their Pd(II) complexes as bioactive agentsInternational Journal of Polymeric Materials and Polymeric Biomaterials, 69
(1967)
Study of pulp structure by infrared spectroscopy
V. Lotfy, A. Basta (2020)
Optimizing the chitosan-cellulose based drug delivery system for controlling the ciprofloxacin release versus organic/inorganic crosslinker, characterization and kinetic study.International journal of biological macromolecules
Kenichiro Hayata, S. Furumi (2019)
Side Chain Effect of Hydroxypropyl Cellulose Derivatives on Reflection PropertiesPolymers, 11
A. Basta, V. Lotfy, J. Micky, A. Salem (2021)
Hydroxypropylcellulose-based liquid crystal materials, 2
M. Bagheri, Leila Pourmirzaei (2013)
Synthesis and characterization of cholesteryl-modified graft copolymer from hydroxypropyl cellulose and its application as nanocarrierMacromolecular Research, 21
A. Coats, J. Redfern (1964)
Kinetic Parameters from Thermogravimetric DataNature, 201
D. Gray (1994)
Chiral nematic ordering of polysaccharidesCarbohydrate Polymers, 25
M. Nelson, R. O’connor (1964)
Relation of certain infrared bands to cellulose crystallinity and crystal lattice type. Part II. A new infrared ratio for estimation of crystallinity in celluloses I and IIJournal of Applied Polymer Science, 8
Peter Ohlendorf, A. Greiner (2015)
Synthesis of liquid crystalline thioether-functionalized hydroxypropyl cellulose estersPolymer Chemistry, 6
Christopher Walters, Charlotte Boott, Thanh-Dinh Nguyen, W. Hamad, M. MacLachlan (2020)
Iridescent Cellulose Nanocrystal Films Modified with Hydroxypropyl Cellulose.Biomacromolecules
(1994)
Comparison of thermal and cholesteric mesophase properties among the three kind of hydroxy propyl cellulose (HPC) derivatives
T. Yamagishi, Y. Nakamoto, P. Sixou (2006)
Preparation and cholesteric mesophase properties of (Butyl-co-pentyl) propylcelluloseCellulose, 13
D. López-Velázquez, A. Hernández-Sosa, E. Pérez (2015)
Effect of the degree of substitution in the transition temperatures and hydrophobicity of hydroxypropyl cellulose esters.Carbohydrate polymers, 125
A. Basta, V. Lotfy, M. Hasanin, P. Trens, H. El-saied (2019)
Efficient treatment of rice byproducts for preparing high-performance activated carbonsJournal of Cleaner Production
V. Thakur, M. Thakur, R. Gupta (2013)
Development of functionalized cellulosic biopolymers by graft copolymerization.International journal of biological macromolecules, 62
Y. Tezuka, K. Imai, M. Oshima, T. Chiba (1990)
Determination of substituent distribution in cellulose ethers by 13C- and 1H-N.M.R. studies of their acetylated derivatives: O-(2-hydroxypropyl)celluloseCarbohydrate Research, 196
A. Basta, V. Lotfy (2021)
Synthesis and evaluating of carbon nanoallotrope‐biomacromolecule gel composites as drug delivery systemsJournal of Applied Polymer Science
W. Hosny, A. Basta, H. El-saied (1997)
Metal Chelates with Some Cellulose Derivatives: V. Synthesis and Characterization of Some Iron(III) Complexes with Cellulose EthersPolymer International, 42
R. Aoki, Masashi Fukawa, S. Furumi (2019)
Preparation of the Color Films from Cellulose Derivatives in a Diacrylate LiquidJournal of Photopolymer Science and Technology
R. Werbowyj, D. Gray (1976)
Liquid Crystalline Structure In Aqueous Hydroxypropyl Cellulose SolutionsMolecular Crystals and Liquid Crystals, 34
A. Basta, V. Lotfy, A. Salem (2021)
Valorization of Biomass Pulping Waste As Effective Additive For Enhancing The Performance of Liquid Crystal Hydroxypropyl Cellulose Nanocomposite Film
B. Senyuk, Qingkun Liu, Ye Yuan, I. Smalyukh (2016)
Edge pinning and transformation of defect lines induced by faceted colloidal rings in nematic liquid crystals.Physical review. E, 93 6
K. Vimala, K. Sivudu, Y. Mohan, B. Sreedhar, K. Raju (2009)
Controlled silver nanoparticles synthesis in semi-hydrogel networks of poly(acrylamide) and carbohydrates: A rational methodology for antibacterial applicationCarbohydrate Polymers, 75
Demiana Hanna, V. Lotfy, A. Basta, G. Saad (2020)
Comparative evaluation for controlling release of niacin from protein- and cellulose-chitosan based hydrogels.International journal of biological macromolecules
P. Ravichandran, P. Sugumaran, S. Seshadri, A. Basta (2018)
Optimizing the route for production of activated carbon from Casuarina equisetifolia fruit wasteRoyal Society Open Science, 5
B. Ateş, Suleyman Koytepe, Ahmet Ulu, C. Gurses, V. Thakur (2020)
Chemistry, Structures, and Advanced Applications of Nanocomposites from Biorenewable Resources.Chemical reviews
A. Basta, V. Lotfy, N. Ghaly, M. Nabil, K. Mohamed (2020)
Bioactivity evaluation of amino acid-conjugates with protein versus cellulose based conjugates and extracted flavonoidsJournal of Drug Delivery Science and Technology, 60
Min‐Hui Li, A. Brûlet, P. Davidson, P. Keller, J. Cotton (1993)
Observation of hairpin defects in a nematic main-chain polyester.Physical review letters, 70 15
H. Arca, Laura Mosquera-Giraldo, Vivian Bi, Daiqiang Xu, L. Taylor, K. Edgar (2018)
Pharmaceutical Applications of Cellulose Ethers and Cellulose Ether Esters.Biomacromolecules, 19 7
Weiwang Chen, W. Weng, M. Fu (2017)
Hydroxypropyl cellulose‐based esters for thermal energy storage by grafting with palmitic‐stearic binary acidsJournal of Applied Polymer Science, 134
Bin Huang, J. Ge, Yonghong Li, Haoqing Hou (2007)
Aliphatic acid esters of (2-hydroxypropyl) cellulose—Effect of side chain length on properties of cholesteric liquid crystalsPolymer, 48
A. Basta, H. El-saied, A. Baraka, V. Lotfy (2017)
Beneficial effect of new activated carbons in enhancing the performance of particle boards from UF-rice strawPigment & Resin Technology, 46
V. Lotfy, N. Fathy, A. Basta (2018)
Novel approach for synthesizing different shapes of carbon nanotubes from rice straw residueJournal of Environmental Chemical Engineering
J. Canejo, Nuno Monge, Coro Echeverria, S. Fernandes, M. Godinho (2017)
Cellulosic liquid crystals for films and fibersLiquid Crystals Reviews, 5
Taku Ishizaki, Shuntaro Uenuma, S. Furumi (2015)
Thermotropic properties of cholesteric liquid crystal from hydroxypropyl cellulose mixed estersKobunshi Ronbunshu, 72
Perihan Khalf‐Alla, A. Basta, V. Lotfy, Safaa Hassan (2020)
Synthesis, Characterization, Speciation, and Biological Studies on Metal Chelates of Carbohydrates with Molecular Docking InvestigationMacromolecular Materials and Engineering
A. Basta, V. Lotfy, J. Micky, A. Salem (2021)
Liquid crystal behavior of cellulose nanoparticles‐ethyl cellulose composites: Preparation, characterization, and rheologyJournal of Applied Polymer Science, 138
H. El-saied, O. El-Hady, A. Basta, C. El-Dewiny, S. Abo-Sedera (2016)
Bio-chemical properties of sandy calcareous soil treated with rice straw-based hydrogelsJournal of the Saudi Society of Agricultural Sciences, 15
Q. Zhang, Liao Qian, Li Wang, S. Stuto, Changyu Shen (2013)
Study of Casting Self-Colored Liquid Crystalline Solid Films of Hydroxypropyl CelluloseApplied Mechanics and Materials, 341-342
A. Idrissi, S. Barkany, H. Amhamdi, A. Maaroufi (2013)
Synthesis and characterization of the new cellulose derivative films based on the hydroxyethyl cellulose prepared from esparto “stipa tenacissima” cellulose of Eastern Morocco. II. Esterification with acyl chlorides in a homogeneous mediumJournal of Applied Polymer Science, 127
I. Dierking (2014)
Chiral Liquid Crystals: Structures, Phases, EffectsSymmetry, 6
Haoqing Hou, Arndt Reuning, J. Wendorff, A. Greiner (2000)
Tuning of the pitch height of thermotropic cellulose estersMacromolecular Chemistry and Physics, 201
Dae‐Sil Lee, A. Perlin (1983)
Use of methanolysis in the characterization of O-(2-hydroxypropyl)cellulose by 13C-n.m.r. spectroscopyCarbohydrate Research, 124
A. Basta, H. El-saied, Vivian Lofty (2014)
Performance assessment of deashed and dewaxed rice straw on improving the quality of RS-based compositesRSC Advances, 4
Ji Kim, T. Han, Sun Lee, J. Kim, C. Ahn, Jei-Moon Yun, S. Kim (2011)
Graphene oxide liquid crystals.Angewandte Chemie, 50 13
This paper aims to study the effect of hydrolysis route of hydroxypropyl cellulose (HPC) on its esterification performance as liquid crystal material. The assessment was carried out from the data of spectra (Fourier-transform infrared analysis [FTIR] and 1H-nuclear magnetic resonance [1H-NMR]), thermal stability as well as optical properties via forming ordered mesophases at lower concentration than HPC.Design/methodology/approachThe HPC was hydrolyzed by hydrochloric acid-methanol at times 9 and 18 h, and the products were esterified by decanoyl chloride. The products of hydrolysis and the esterification were characterized by FTIR, NMR, nonisothermal analysis, thermo-gravimetric analysis (TGA) and polarizing microscope to evaluate the role of degree of substitution of HPC as a result of hydrolysis, on esterification degree, thermal stability and thermal and liquid crystal behavior of the final esterified HPC.FindingsThe pretreatment by acid hydrolysis of HPC was successful for synthesizing novel cholesteric hydroxypropyl cellulose ester. The data of FTIR and TGA thermal analysis proved that hydrolysis and esterification of HPC with the decanoyl chain significantly enhanced crystallinity of this cellulose derivative from 0.57 to (1.7–1.9). Moreover, they provided products with superior thermal stability than pure HPC, as noticed from increasing the activation energy of degradation (Ea) from 514.3 to 806.2 kJ/mol. The NMR measurement proved that hydrolysis of HPC for 9 and 18 h decreased the degree of substitution from 3 to 2.1 and 1.3, respectively. Moreover, the esterified HPC showed a promising birefringence texture (chiral nematic) besides decreasing the critical concentration from 30% for HPC to 10% for the esterified unhydrolyzed HPC, while superior decreasing to 1–5% was observed for the esterified hydrolyzed HPC.Research limitations/implicationsThere are two stages for preparation of decanoyl ester hydroxypropyl cellulose. At the first stage, HPC was treated by hydrochloric acid-methanol in ratio 1:10 at times 9 and18 h. At the second stage, HPC and hydrolyzed HPC were refluxed with decanoyl chloride (1:6) in presence of nitrogen atmosphere. The final product was precipitated by distilled water.Practical implicationsThere are two stages for preparation of decanoyl ester hydroxypropyl cellulose. At the first stage, HPC was treated by hydrochloric acid-methanol in ratio 1:10 at times 9 and18 h. At the second stage, HPC and hydrolyzed HPC were refluxed with decanoyl chloride (1:6) in presence of nitrogen atmosphere. The final product was precipitated by distilled water.Originality/valueThe novelty of this work was focused on enhancing the crystallinity, thermal stability and liquid crystal behavior of esterified HPC, via decreasing the degree of substitution and consequently the type of OH group subjected to esterification. The decanoyl ester formation from the hydrolyzed hydroxypropyl cellulose is able to form ordered mesophases at even low concentration (promising birefringence texture at concentrations 1–5%). It is worthy to notice that the investigated route is able to omit the role of graphene oxide in promoting the liquid crystal behavior of HPC, as it hasn't any effect on critical concentration. This work will promote the use of HPC in technological applications, e.g. high modulus fibers and electronic devices.
Pigment & Resin Technology – Emerald Publishing
Published: Jan 27, 2023
Keywords: Cellulose ether; Hydrolysis; Decanoyl acid chloride; Cellulose-based optical material; Graphene nanocomposite; Lyotropic
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.