Kinetic and Thermodynamic Evidence of the Paal–Knorr and Debus–Radziszewski Reactions Underlying Formation of Pyrroles and Imidazoles in Hydrothermal Liquefaction of Glucose–Glycine Mixtures

Sudibyo, Hanifrahmawan; Budhijanto, Budhijanto; Cabrera, Daniela V.; Mahannada, Aqiela; Marbelia, Lisendra; Prasetyo, Dwi Joko; Anwar, Muslih

doi:10.1021/acs.energyfuels.3c05051

Cited by 3 publications

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References 53 publications

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“…While Long et al observed how two-stage HTL can weaken the Maillard reaction pathway, having a low-pH played an important role for further inhibition of such a reaction leading to reduction in N content (Table ) and reduced % area of N-heterocyclics and amides/amines (Table ) in the bio-oils. Some N-compounds were still detected under acidic conditions due to alternate reaction mechanisms including formation of pyrroles and imidazoles from Paal-Knorr and Debus-Radziszewski reactions involving dicarbonyls, primary amine, and ammonia . Phenols detected in bio-oils can also be attributed to lignin degradation .…”

Section: Resultsmentioning

confidence: 99%

Direct and Two-Stage Hydrothermal Liquefaction of Chicken Manure: Impact of Reaction Parameters on Biocrude Oil Upgradation

Vadlamudi,

Pecchi,

Sudibyo

et al. 2024

ACS Sustainable Chem. Eng.

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Hydrothermal liquefaction (HTL) provides advantages to traditional methods (e.g., landfilling and composting) to convert wet biomass waste (e.g., agricultural residue) into energy-rich biocrude oil (bio-oil) and nutrient-rich aqueous phase. The challenge associated with these feedstocks lies in their high N and O contents. These heteroatoms are fixed into bio-oil produced from direct-HTL, making it infeasible as a drop-in fuel due to the low calorific value. To address these challenges for chicken manure, this study evaluated two thermochemical conversion approaches: (1) direct-HTL and (2) a two-stage process of hydrothermal carbonization (HTC) followed by HTL. The second scenario aimed to extract most N and oxygenates into the aqueous phase, producing C-rich bio-oil from the second stage (i.e., HTL). Experiments were conducted at different temperatures (160− 350 °C), reaction times (30−60 min), and feedstock pHs (4−9). Acidic conditions were achieved by adding acetic acid as a catalyst, whereas the natural feedstock pH of chicken manure was around 9. Experiments revealed that the bio-oil properties improved from two-stage processing of acidic feedstock with pH = 4−5 with HTC conducted at 190 °C for 30 min and HTL at 300 °C for 30 min. Due to reduced O and N contents, the higher heating value of bio-oil increased from 32−33 (direct-HTL) to 37−38 MJ/kg (twostage). Nonetheless, the overall C recovery in the bio-oil decreased from ∼35 to ∼20% compared with direct-HTL. This shows a trade-off between removing as many heteroatoms as possible and maximizing C recovery in bio-oil. A mechanistic study revealed the underlying degradation mechanisms (dehydration, decarboxylation, and denitrogenation) in direct-HTL and two-stage along with inhibition of Maillard reaction under the acidic environment.

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Section: Resultsmentioning

confidence: 99%