Hydrothermal
liquefaction (HTL) is a promising technique for conversion
of wet biomasses containing varying amounts of carbohydrate, protein,
lipid, and lignin. In this work, mixtures of these model compounds
were subjected to HTL at 335 °C. As many as 67 compounds were
quantitated in the aqueous phase, including small organic acids, cyclic
oxygenates, fatty acids, nitrogenates, and oxygenated aromatics. The
concentrations correlated with the ratio of the model compounds. Principal
component analysis separated samples on the basis of their quantitative
results which could be linked to their biochemical composition. Concentrations
of the analytes were modeled with partial least squares regression,
and high-quality predictions were made from quality control (QC) samples
and to varying degrees from Dried Distillers Grains with Solubles
(DDGS), Miscanthus x giganteus,
and Chlorella vulgaris. Values for total organic carbon (TOC), total nitrogen
(TN), and pH were also predicted from QC samples, DDGS, M. x giganteus, and C. vulgaris.
Carbohydrate and lipid contents mainly influenced TOC values and could
be used for minimizing loss of organics, for techno-economic analysis,
and for assessing potential for anaerobic digestion and thermal gasification.
Pyrazines were modeled using linear, exponential, and second-degree
polynomial fits, depending on whether carbohydrate or protein was
the limiting biochemical component, which could be a way of controlling
nitrogen and carbon displacement to the aqueous phase. This work shows
that TOC, TN, pH, and concentrations of single compounds in the aqueous
phase from HTL can, in many cases, be predicted from HTL of mixtures
of biomass constituents.
