A new carbohydrate retaining variety of Miscanthus increases biogas methane yields compared to M x giganteus and narrows the yield advantage of maize

A new carbohydrate retaining variety of Miscanthus increases biogas methane yields compared to M x giganteus and narrows the yield advantage of maize

Abstract Anaerobic digestion (AD) currently relies heavily on crop feedstocks to maintain a constant output. A major annual crop used is Zea mays (maize), but this practice presents significant concerns because high energy inputs and food‐growing land are required for cultivation. The autumn harvest...

Full description

Bibliographic Details
Main Authors: Jason Kam, David Thomas, Sandra Pierre, Chris Ashman, Jon P. McCalmont, Sarah J. Purdy
Format: Article
Language:English
Published: Wiley 2020-08-01
Series:Food and Energy Security
Subjects:
anaerobic digestion
cellulose
energy
lignin
Miscanthus
nonstructural carbohydrate
Online Access:https://doi.org/10.1002/fes3.224
id doaj-bef85f95cb904de48fe21ac732e01423
record_format Article
spelling doaj-bef85f95cb904de48fe21ac732e014232021-04-02T11:25:55ZengWileyFood and Energy Security2048-36942020-08-0193n/an/a10.1002/fes3.224A new carbohydrate retaining variety of Miscanthus increases biogas methane yields compared to M x giganteus and narrows the yield advantage of maizeJason Kam0David Thomas1Sandra Pierre2Chris Ashman3Jon P. McCalmont4Sarah J. Purdy5Institute of Biological, Environmental and Rural Sciences Aberystwyth University Aberystwyth UKInstitute of Biological, Environmental and Rural Sciences Aberystwyth University Aberystwyth UKInstitute of Biological, Environmental and Rural Sciences Aberystwyth University Aberystwyth UKInstitute of Biological, Environmental and Rural Sciences Aberystwyth University Aberystwyth UKCollege of Life and Environmental Science Exeter University Exeter UKThe University of Sydney I.A Watson Grains Research Institute Narrabri NSW AustraliaAbstract Anaerobic digestion (AD) currently relies heavily on crop feedstocks to maintain a constant output. A major annual crop used is Zea mays (maize), but this practice presents significant concerns because high energy inputs and food‐growing land are required for cultivation. The autumn harvest date of maize exposes soils over winter resulting in erosion and runoff into waterways. Miscanthus is physiologically and morphologically similar to maize. It is also of interest for biogas generation. As a perennial grass, Miscanthus requires far less input and can be grown on land that is unsuitable for food crops. It is typically harvested in late winter to early spring. Maize produces higher biogas yields than the most commonly grown commercial variety of Miscanthus (Mxg), because it has a higher nonstructural carbohydrate (NSC) concentration that facilitates the AD process. We aimed to investigate whether a new Miscanthus hybrid (“GNT‐14”) that was bred from a high carbohydrate accumulating parental type can improve biogas yield from Mxg. Comparisons were made on biogas yields at two time points, October and January; the NSC, cellulose, and lignin concentrations were quantified; and the contribution of the NSC to biogas yield was determined by comparing intact and washed samples. The NSC concentrations of GNT‐14 were fivefold higher than Mxg in January, and a 28% increase in methane was observed. While Mxg showed a reduction in methane yields (L/kg) from biomass harvested in January compared to October, GNT‐14 showed no such decline. Although the potential methane yields of GNT‐14 were only 70% that of maize, the energy input (GJ ha‐1) required for cultivation was 26% of maize. Our results demonstrated that GNT‐14 could be harvested later than maize for biogas generation, offering soil protection over winter. We encourage Miscanthus breeding efforts to focus on NSC concentration as well as yield.https://doi.org/10.1002/fes3.224anaerobic digestioncelluloseenergyligninMiscanthusnonstructural carbohydrate
collection DOAJ
language English
format Article
sources DOAJ
author Jason Kam
David Thomas
Sandra Pierre
Chris Ashman
Jon P. McCalmont
Sarah J. Purdy
spellingShingle Jason Kam
David Thomas
Sandra Pierre
Chris Ashman
Jon P. McCalmont
Sarah J. Purdy
A new carbohydrate retaining variety of Miscanthus increases biogas methane yields compared to M x giganteus and narrows the yield advantage of maize
Food and Energy Security
anaerobic digestion
cellulose
energy
lignin
Miscanthus
nonstructural carbohydrate
author_facet Jason Kam
David Thomas
Sandra Pierre
Chris Ashman
Jon P. McCalmont
Sarah J. Purdy
author_sort Jason Kam
title A new carbohydrate retaining variety of Miscanthus increases biogas methane yields compared to M x giganteus and narrows the yield advantage of maize
title_short A new carbohydrate retaining variety of Miscanthus increases biogas methane yields compared to M x giganteus and narrows the yield advantage of maize
title_full A new carbohydrate retaining variety of Miscanthus increases biogas methane yields compared to M x giganteus and narrows the yield advantage of maize
title_fullStr A new carbohydrate retaining variety of Miscanthus increases biogas methane yields compared to M x giganteus and narrows the yield advantage of maize
title_full_unstemmed A new carbohydrate retaining variety of Miscanthus increases biogas methane yields compared to M x giganteus and narrows the yield advantage of maize
title_sort new carbohydrate retaining variety of miscanthus increases biogas methane yields compared to m x giganteus and narrows the yield advantage of maize
publisher Wiley
series Food and Energy Security
issn 2048-3694
publishDate 2020-08-01
description Abstract Anaerobic digestion (AD) currently relies heavily on crop feedstocks to maintain a constant output. A major annual crop used is Zea mays (maize), but this practice presents significant concerns because high energy inputs and food‐growing land are required for cultivation. The autumn harvest date of maize exposes soils over winter resulting in erosion and runoff into waterways. Miscanthus is physiologically and morphologically similar to maize. It is also of interest for biogas generation. As a perennial grass, Miscanthus requires far less input and can be grown on land that is unsuitable for food crops. It is typically harvested in late winter to early spring. Maize produces higher biogas yields than the most commonly grown commercial variety of Miscanthus (Mxg), because it has a higher nonstructural carbohydrate (NSC) concentration that facilitates the AD process. We aimed to investigate whether a new Miscanthus hybrid (“GNT‐14”) that was bred from a high carbohydrate accumulating parental type can improve biogas yield from Mxg. Comparisons were made on biogas yields at two time points, October and January; the NSC, cellulose, and lignin concentrations were quantified; and the contribution of the NSC to biogas yield was determined by comparing intact and washed samples. The NSC concentrations of GNT‐14 were fivefold higher than Mxg in January, and a 28% increase in methane was observed. While Mxg showed a reduction in methane yields (L/kg) from biomass harvested in January compared to October, GNT‐14 showed no such decline. Although the potential methane yields of GNT‐14 were only 70% that of maize, the energy input (GJ ha‐1) required for cultivation was 26% of maize. Our results demonstrated that GNT‐14 could be harvested later than maize for biogas generation, offering soil protection over winter. We encourage Miscanthus breeding efforts to focus on NSC concentration as well as yield.
topic anaerobic digestion
cellulose
energy
lignin
Miscanthus
nonstructural carbohydrate
url https://doi.org/10.1002/fes3.224
work_keys_str_mv AT jasonkam anewcarbohydrateretainingvarietyofmiscanthusincreasesbiogasmethaneyieldscomparedtomxgiganteusandnarrowstheyieldadvantageofmaize
AT davidthomas anewcarbohydrateretainingvarietyofmiscanthusincreasesbiogasmethaneyieldscomparedtomxgiganteusandnarrowstheyieldadvantageofmaize
AT sandrapierre anewcarbohydrateretainingvarietyofmiscanthusincreasesbiogasmethaneyieldscomparedtomxgiganteusandnarrowstheyieldadvantageofmaize
AT chrisashman anewcarbohydrateretainingvarietyofmiscanthusincreasesbiogasmethaneyieldscomparedtomxgiganteusandnarrowstheyieldadvantageofmaize
AT jonpmccalmont anewcarbohydrateretainingvarietyofmiscanthusincreasesbiogasmethaneyieldscomparedtomxgiganteusandnarrowstheyieldadvantageofmaize
AT sarahjpurdy anewcarbohydrateretainingvarietyofmiscanthusincreasesbiogasmethaneyieldscomparedtomxgiganteusandnarrowstheyieldadvantageofmaize
AT jasonkam newcarbohydrateretainingvarietyofmiscanthusincreasesbiogasmethaneyieldscomparedtomxgiganteusandnarrowstheyieldadvantageofmaize
AT davidthomas newcarbohydrateretainingvarietyofmiscanthusincreasesbiogasmethaneyieldscomparedtomxgiganteusandnarrowstheyieldadvantageofmaize
AT sandrapierre newcarbohydrateretainingvarietyofmiscanthusincreasesbiogasmethaneyieldscomparedtomxgiganteusandnarrowstheyieldadvantageofmaize
AT chrisashman newcarbohydrateretainingvarietyofmiscanthusincreasesbiogasmethaneyieldscomparedtomxgiganteusandnarrowstheyieldadvantageofmaize
AT jonpmccalmont newcarbohydrateretainingvarietyofmiscanthusincreasesbiogasmethaneyieldscomparedtomxgiganteusandnarrowstheyieldadvantageofmaize
AT sarahjpurdy newcarbohydrateretainingvarietyofmiscanthusincreasesbiogasmethaneyieldscomparedtomxgiganteusandnarrowstheyieldadvantageofmaize
_version_ 1724164847028928512

Similar Items