Reactions of a-substituted non-phenolic lignin model compounds under alkaline hydrolysis conditions

Mirshokraie, S. Ahmad (Seyed Ahmad)

January 1988

Side-chain ether groups in lignin model compounds of the general structure 1-(3$ sp prime$,4$ sp prime$-dimethoxyphenyl)-1,2-diaryloxyethane exhibited hydrolytic cleavage (the extent depending on the substituents on the 1-aryloxy groups) in aqueous 2N NaOH at 150$ sp circ$C (i.e. under wood pulping conditions). The level of hydrolysis increased in phenylpropane models (i.e. with $ gamma$-CH$ sb2$OH). Thus the commonly accepted generalization that 1,2-diethers of 3$ sp prime$,4$ sp prime$-dimethyoxyphenylpropane are stable in hot alkali is valid only for 1-alkoxy compounds. The newly observed hydrolytic cleavage is influenced by a combination of steric effects, electronic effects and solubility parameters. These observations now make it possible to consider alkaline delignification in the light of gel-degradation theory. / A series of compounds of the general structure 1-(3$ sp prime$-4$ sp prime$,dimethoxyphenyl)-1-aryl-2-guaiacyloxyethane, where the 1-aryl group bore a hydroxy substituent, also exhibited alkaline hydrolysis, at 150$ sp circ$C, at the $ beta$-carbon. The extent was greater when the 1-aryl group bore an $o$-OH than when it bore a $p$-OH. Thus, the reaction was assisted by the nucleophilic attack of the $o$-phenoxide anion on the $ beta$-carbon. / A relatively high release of guaiacol occurred on treatment of 1-(3$ sp prime$,4$ sp prime$-dimethoxyphenyl)-1-thio-2-guaiacyloxyethane with 2N NaOH at 150$ sp circ$C, and the yield of guaiacol was increased when the terminal sidechain carbon bore a $-$CH$ sb2$OH group. Analogous $ alpha$-thioaryl and $ alpha$-thioalkyl compounds also exhibited greater ether cleavage than their oxy counterparts. The hydrolysis of the $ beta$-guaiacyl group was also enhanced by the presence of $ alpha$-seleno-containing groups.

Lignin

Wood -- Chemistry

Improved pulping efficiency in C4H-F5H transformed poplar

Huntley, Shannon Kelly

11 1900

Changes in wood chemistry could have significant impact on both environmental and economic aspects of the pulp and paper industry. Consequently, a considerable amount of effort has been devoted to altering lignin content and/or modifing lignin monomer composition, a cell wall component whose removal is a major part of the chemical pulping process. Analysis of poplar transformed with a cinnamate 4-hydroxylase (C4H):ferulate5-hydroxylase (F5H) construct confirmed significant increases in the mole percent syringyl lignin in transgenic lines. Further, this study demonstrated significant increases in pulping efficiency from greenhouse grown transgenic trees. Compared to wild-type pulp, decreases of 23 kappa units (residual lignin) and increases of >20 ISO brightness units were observed in tree lines exhibiting high syringyl monomer concentrations (93.5% mol S). These changes were associated with no significant change in total lignin content or observed phenotypic differences in the trees. Additionally, pulp yields were not affected by the enhanced removal of lignin.. Furthermore, transgenic lines exhibit reduced fibre coarseness and increased cellulose viscosity. These results suggest that C4H-F5H transformed trees could be used to produce pulp for paper with substantially less severe delignification conditions (lower chemical loading or less energy), and that the pulp produced is of comparable quality to that of the wild-type poplar. Consequently, the ecological footprint left on the environment, measured by the amount of deleterious pulping by-products released into the environment may be significantly reduced.

Wood -- Chemistry

Lignin

Pulping

The distribution of phenolic hydroxyl groups in the xylem tissue of softwoods /

Yang, Juei-Mao

January 1977

No description available.

Wood -- Chemistry.

Xylem.

High temperature steam hydrolysis of tulip poplar

Fieber, Catherine Ann

08 1900

No description available.

Hydrolysis

Wood Chemistry

Recovery of byproducts in the formation of cellulose pulp by high pressure steam hydrolysis of hardwoods

Mann, Timothy Marvin

05 1900

No description available.

Wood Chemistry

Cellulose

The fractionation of lignocellulosics

Bonanno, Michael Anthony

08 1900

No description available.

Lignin

Wood Chemistry

Chlorite delignification of spruce wood.

Ahlgren, Per Arne

January 1970

No description available.

Lignin

Wood -- Chemistry

Chlorites

The topochemistry of delignification reactions.

Wood, John Russell.

January 1972

No description available.

Lignin

Wood -- Chemistry

The distribution of lignin in aspen wood.

Musha, Yoshinori.

January 1970

No description available.

Aspen

Lignin

Wood -- Chemistry

Physico-chemical mechanisms of delignification

Kerr, Allan J.

January 1974

No description available.

Lignin.

Wood -- Chemistry.