Christopher S Lancefield
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Explore the profile of Christopher S Lancefield including associated specialties, affiliations and a list of published articles.
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Articles
21
Citations
286
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Recent Articles
1.
Constant S, Lancefield C, Vogelzang W, Pazhavelikkakath Purushothaman R, Frissen A, Houben K, et al.
Green Chem
. 2024 Jul;
26(13):7739-7751.
PMID: 38957875
Humins, (side-)products of the acid-catalysed dehydration of carbohydrates, will be produced in substantial quantities with the development of industrial biorefining processes. Most structural knowledge about such humins is based on...
2.
Moller S, Lancefield C, Oates N, Simister R, Dowle A, Gomez L, et al.
Front Plant Sci
. 2022 Aug;
13:926300.
PMID: 35937377
Ester-linked hydroxycinnamic acids ferulic acid (FA) and para-coumaric acid (-CA) play important roles in crosslinking within cell wall arabinoxylans (AX) and between AX and lignin in grass cell walls. The...
3.
Lancefield C, Folker B, Cioc R, Stanciakova K, Bulo R, Lutz M, et al.
Angew Chem Int Ed Engl
. 2021 Apr;
60(17):9171.
PMID: 33844404
No abstract available.
4.
Lancefield C, Folker B, Cioc R, Stanciakova K, Bulo R, Lutz M, et al.
Angew Chem Int Ed Engl
. 2020 Sep;
59(52):23480-23484.
PMID: 32885556
A novel route for the production of the versatile chemical building block phthalide from biorenewable furfuryl alcohol and acrylate esters is presented. Two challenges that limit sustainable aromatics production via...
5.
Lahive C, Kamer P, Lancefield C, Deuss P
ChemSusChem
. 2020 Jun;
13(17):4238-4265.
PMID: 32510817
The development of fundamentally new valorization strategies for lignin plays a vital role in unlocking the true potential of lignocellulosic biomass as sustainable and economically compatible renewable carbon feedstock. In...
6.
Xiao G, Montgomery J, Lancefield C, Panovic I, Westwood N
Chemistry
. 2020 May;
26(54):12397-12402.
PMID: 32378750
Selective processing of the β-O-4 unit in lignin is essential for the efficient depolymerisation of this biopolymer and therefore its successful integration into a biorefinery set-up. An approach is described...
7.
Montgomery J, Lancefield C, Miles-Barrett D, Ackermann K, Bode B, Westwood N, et al.
ACS Omega
. 2019 Aug;
2(11):8466-8474.
PMID: 31457383
One key challenge hindering the valorization of lignin is its structural complexity. Artificial lignin-like materials provide a stepping stone between the simplicity of model compounds and the complexity of lignin....
8.
Lancefield C, Constant S, de Peinder P, Bruijnincx P
ChemSusChem
. 2019 Jan;
12(6):1139-1146.
PMID: 30641616
Lignin is an attractive material for the production of renewable chemicals, materials and energy. However, utilization is hampered by its highly complex and variable chemical structure, which requires an extensive...
9.
Panovic I, Lancefield C, Phillips D, Gronnow M, Westwood N
ChemSusChem
. 2018 Dec;
12(2):542-548.
PMID: 30537171
Chemically modified lignins are important for the generation of biomass-derived materials and as precursors to renewable aromatic monomers. A butanol-based organosolv pretreatment has been used to convert an abundant agricultural...
10.
Lancefield C, Wienk H, Boelens R, Weckhuysen B, Bruijnincx P
Chem Sci
. 2018 Oct;
9(30):6348-6360.
PMID: 30310563
Kraft lignin, the main by-product of the pulping industry, is an abundant, yet highly underutilized renewable aromatic polymer. During kraft pulping, the lignin undergoes extensive structural modification, with many labile...