Abstract

Miscanthus is a fast-growing perennial grass that attracts significant attention for its potential application as a feedstock for bioethanol production. This report explores the difference in the lignocellulosic composition of various Miscanthus cultivars, including Miscanthus × giganteus cultivated at the same location (mainly Lincoln, UK). It also assesses the sugar release profiles and mineral composition profiles of five Miscanthus cultivars harvested over a growing period from November 2018 to February 2019. The results showed that Miscanthus × giganteus contains approximately 45.5% cellulose, 29.2% hemicellulose and 23.8% lignin (dry weight, w/w). Other cultivars of Miscanthus also contain high quantities of carbohydrates (cellulose 41.1–46.0%, hemicellulose 24.3–32.6% and lignin 21.4–24.9%). Pre-treatment of Miscanthus using dilute acid followed by enzymatic hydrolysis released 63.7–80.2% of the theoretical glucose content. Fermentation of a hydrolysate of Miscanthus × giganteus using Saccharomyces cerevisiae NCYC2592 produced 13.58 ± 1.11 g/L of ethanol from 35.13 ± 0.46 g/L of glucose, corresponding to a yield of 0.148 g/g dry weight Miscanthus biomass. Scanning electron microscopy was used to study the morphology of raw and hydrolysed Miscanthus samples, which provided visual proof of Miscanthus lignocellulose degradation in these processes. The sugar release profile showed that a consequence of Miscanthus plant growth is an increase in difficulty in releasing monosaccharides from the biomass. The potassium, magnesium, sodium, sulphur and phosphorus contents in various Miscanthus cultivars were analysed. The results revealed that these elements were slowly lost from the plants during the latter part of the growing season, for a specific cultivar, until February 2019.

Highlights

  • The use of fossil fuels has been crucial to the development of modern civilisation and is an indispensable resource to the global population

  • The analysis revealed that Miscanthus cultivar B (BE04) had the highest α-cellulose content (48.09 ± 0.26%), and, unlike the other cultivars, the early harvest sample (BE04) had a higher cellulose content compared to the late-harvested sample (BE10)

  • The determination of cellulose content revealed that all Miscanthus samples contained promising amounts of cellulose for bioethanol production

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Summary

Introduction

The use of fossil fuels has been crucial to the development of modern civilisation and is an indispensable resource to the global population. Miscanthus spp. grass has become a popular bioenergy feedstock in the UK and worldwide due to its high crop yield (8–32 tonne/ha) and high energy output (140–560 GJ/ha) relative to other feedstocks [1]. It has been cultivated for environmental remediation, such as CO2 fixation [2] and heavy metal remediation [3]. This paper reports the sugar and mineral composition profiles of 5 Miscanthus cultivars during the November 2018 to February 2019 season, providing the information for the selection of the best harvest point of the biomass

Miscanthus Samples
Lignin Composition Analysis by the Klason Method
Miscanthus Morphology Analysis Using Scanning Electron Microscopy
Miscanthus Pre-Treatment and Enzymatic Saccharification
Yeast Fermentation
Sugar and Ethanol Analysis
Element Content Analysis Using ICP-MS
Comparison of Lignin Content Using the Klason Method or ABSL Method
Carbohydrate Composition of Miscanthus Cultivars
Miscanthus Cultivar Hydrolysis and Fermentation
Analysis of Miscanthus Structure Using Scanning Electron Microscopy
Pre-treatment of Miscanthus andand thethe fermentation of Miscanthus
Analysis
Sugar Profiles of Miscanthus Cultivars through a Growing Season
14 December
Elemental
14 December 2018 and Cultivars in Cultivars
Elemental Composition of Cultivars through the Growing Season
Findings
Conclusions and Future Work

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