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IK Sataev, LE Tikhonova, KS Akhmedov (1974)
Gidrol. Lesokhim. Prom-st.?
YuN Kukushkin (1997)
Soros. Obrazovatel?n. Zh., Khim.
KG Bogolitsyn, NM Gorbova, MF Kiryushina (2002)
Lesn. Zh.
SS Khviyuzov (2009)
Acid-Base Properties of Lignin in a Water-Aprotic Solvent System, Cand. Sci. Dissertation
SM Krutov, MYa Zarubin, YuN Sazanov (2011)
Ligniny
GV Vinogradov, AYa Malkin (1977)
Reologiya polimerov
VYa Varshavskii (1989)
Prom-st? Khim. Volokon, NIIEEKhIM
AA Varfolomeev, AD Sinegibskaya, AF Gogotov (2009)
Khim. Rastit. Syr?ya
BV Bogomolov, IS Dorokhina, VS Klimenkov (1962)
Khim. Volokna
DW Krevelen (1990)
Properties of Polymers
Composite precursor based on hydrolytic lignin and polyacrylonitrile was obtained and fibrous composite materials were formed at 80: 20 to 40: 60 ratios between the starting components. A probable mechanism is suggested by which products of cocarbonization of lignin and polyacrylonitrile are formed, with 80–90 wt % carbonized residue produced in an inert atmosphere.
Russian Journal of Applied Chemistry – Springer Journals
Published: Jul 24, 2013
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