Dehydration of lactic acid to acrylic acid over lanthanum phosphate catalysts: the role of Lewis acid sites

Guo, Zhen; Theng, De Sheng; Tang, Karen Yuanting; Zhang, Li Li; Huang, Lin; Borgna, Armando; Wang, Chuan

doi:10.1039/c6cp04163a

Cited by 33 publications

(42 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In addition to the previously mentioned alkaline‐earth phosphate materials, lanthanum and cerium phosphates have also been reported as catalysts yielding AA with 52 and 64 % of selectivity, respectively.…”

Section: Chemical Routes Of Acrylic Acidmentioning

confidence: 97%

Bio‐Acrylates Production: Recent Catalytic Advances and Perspectives of the Use of Lactic Acid and Their Derivates

et al. 2018

View full text Add to dashboard Cite

The production of drop‐in chemicals from bio‐based renewable sources is gaining a lot of momentum due to proven negative impact of fossil‐based economy on environment and society. In this Review, various bio‐derived platform molecules are assessed as renewable alternatives to fossil resources for the catalytic production of acrylates. Acrylic acid and its esters are key building blocks of a large number of high‐value oligomers and polymers in the current industry. In spite of the encouraging successes reported on gram or lab‐scale, real implementation of bio‐based examples remain scarce mainly due to the current high cost and limited availability of the bio‐based substrates. As lactic acid and their derivatives are one of the most promising feedstocks for bio‐acrylate production, they are the main focus of this Review.

show abstract

Section: Chemical Routes Of Acrylic Acidmentioning

confidence: 97%

Bio‐Acrylates Production: Recent Catalytic Advances and Perspectives of the Use of Lactic Acid and Their Derivates

et al. 2018

View full text Add to dashboard Cite

show abstract

“…52 This chemical is also of interest as a chemical platform, and can be subject to multiple transformations. Both small compounds, such as propylene glycol 22,53,54 or acrylic acid, 55,56 and high molecular weight polymers, such as biodegradable poly(lactic acid) polymers can be produced from LA (Fig. 3).…”

Section: Lactic Acid Productionmentioning

confidence: 99%

Products of sugar beet processing as raw materials for chemicals and biodegradable polymers

et al. 2018

View full text Add to dashboard Cite

show abstract

“…1,2,7,12−17 Likely, the catalytic performance for the vapor-phase LA conversion promoted investigators to shed light on the LA reaction mechanism and catalytic active species on various catalyst systems. 12,16,18−25 Miller and co-workers earlier studied the vapor-phase LA conversion mechanism on catalyst surfaces by means of IR, NMR, and GC/MS analyses of surface species apart from catalytic testing and kinetics. 18−22,26 They discovered that low temperatures (<320 °C) and elevated pressures favor 2,3-pentanedione (2,3-PD) formation, whereas high temperatures and low pressures benefit AA and CH 3 CHO production.…”

Section: Introductionmentioning

confidence: 99%

In Situ-Generated Supported Potassium Lactate: Stable Catalysis for Vapor-Phase Dehydration of Lactic Acid to Acrylic Acid

et al. 2019

Self Cite

View full text Add to dashboard Cite

We have studied unsupported, silica gel- and amorphous silica–alumina-supported catalysts derived from K salts for the vapor-phase dehydration of lactic acid (LA) to acrylic acid (AA). A catalytic study shows that the supported catalysts improve the activity and selectivity for the production of AA and decrease the selectivity for the production of propionic acid (PA). The silica–alumina-supported catalysts remain fairly stable in the catalytic performance during 90 h of reaction. The IR spectroscopic characterization combined with the catalytic study demonstrates that potassium lactate (C 3 H 5 KO 3 ) in situ generated from LA and a K salt is an important reaction intermediate for the production of AA and the catalytic stability is associated with the chemical stability of C 3 H 5 KO 3 and the activity for the regeneration of C 3 H 5 KO 3 in the catalytic cycle. On silica–alumina, C 3 H 5 KO 3 is well stabilized and smoothly regenerated during the reaction, leading to the good catalytic stability. This work suggests for the first time that lactate salt acts as the true catalytic active species for the dehydration of LA to AA. We also propose a predominant reaction pathway for the vapor-phase dehydration of LA to AA with K salt catalyst systems.

show abstract

Dehydration of lactic acid to acrylic acid over lanthanum phosphate catalysts: the role of Lewis acid sites

Cited by 33 publications

References 43 publications

Bio‐Acrylates Production: Recent Catalytic Advances and Perspectives of the Use of Lactic Acid and Their Derivates

Bio‐Acrylates Production: Recent Catalytic Advances and Perspectives of the Use of Lactic Acid and Their Derivates

Products of sugar beet processing as raw materials for chemicals and biodegradable polymers

In Situ-Generated Supported Potassium Lactate: Stable Catalysis for Vapor-Phase Dehydration of Lactic Acid to Acrylic Acid

Contact Info

Product

Resources

About