Estimating potential harvestable biomass for bioenergy from sustainably managed private native forests in Southeast Queensland, Australia

Ngugi, Michael R.; Neldner, Victor J.; Ryan, Sean F.; Lewis, Tom; Li, Jiaorong; Norman, Phillip; Mogilski, Michelle

doi:10.1186/s40663-018-0129-z

Cited by 15 publications

(14 citation statements)

References 27 publications

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“…In eighteen of these studies, the theoretical biomass potential is combined with the assessment of either available, technological, economical or environmental biomass potentials. Various studies have used allometric equations to predict the theoretical biomass potential based on in-field measures of height and diameter allowing them to estimate the overall above-ground biomass ratios [54][55][56][57][58][59][60]. For the purpose of bioenergy, these studies are rather informative literature on the ratio of above-ground biomass in order to assess the theoretical biomass potential without including any losses or alternative uses of the biomass.…”

Section: Theoretical Biomass Potentialmentioning

confidence: 99%

A Review on the Potential of Forest Biomass for Bioenergy in Australia

et al. 2020

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The use of forest biomass for bioenergy in Australia represents only 1% of total energy production but is being recognized for having the potential to deliver low-cost and low-emission, renewable energy solutions. This review addresses the potential of forest biomass for bioenergy production in Australia relative to the amount of biomass energy measures available for production, harvest and transport, conversion, distribution and emission. Thirty-Five Australian studies on forest biomass for bioenergy are reviewed and categorized under five hierarchical terms delimiting the level of assessment on the biomass potential. Most of these studies assess the amount of biomass at a production level using measures such as the allometric volume equation and form factor assumptions linked to forest inventory data or applied in-field weighing of samples to predict the theoretical potential of forest biomass across an area or region. However, when estimating the potential of forest biomass for bioenergy production, it is essential to consider the entire supply chain that includes many limitations and reductions on the recovery of the forest biomass from production in the field to distribution to the network. This review reiterated definitions for theoretical, available, technological, economic and environmental biomass potential and identified missing links between them in the Australian literature. There is a need for further research on the forest biomass potential to explore lower cost and lowest net emission solutions as a replacement to fossil resources for energy production in Australia but methods the could provide promising solutions are available and can be applied to address this gap.

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Section: Theoretical Biomass Potentialmentioning

confidence: 99%

A Review on the Potential of Forest Biomass for Bioenergy in Australia

et al. 2020

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“…Data for the study were gathered from the Tarai region of Nepal and the Southeast region of Queensland. The case study site in Nepal is rich in commercially high-value natural forests dominated by Sal (Shorea robusta) [31] whereas the Queensland site is rich in high-value native hardwood timber with a dominance of Spotted gum (Corymbia maculata) [32]. Specifically, the Nawalparasi district of Nepal and the Withcott area of Queensland were selected for study, considering the availability of ongoing forest harvesting blocks (Figure 1).…”

Section: Study Sitesmentioning

confidence: 99%

“…For this purpose, stem density is the key and a sensitive factor as this determines the tree biomass [45]. Therefore, the average density of a commercially matured tree of each species was cited in the earlier studies: Forest Resource Assessment of the Department of Forest Research and Survey (FRA/DFRS) [31], Sharma and Pukkala [35] in the case of Nepal and Maraseni [46] in Queensland. Since the harvested trees were mature (over 30 years of age), the density of Spotted gum in Queensland was taken as 802 kg per m 3 [40].…”

Section: Biomass and Carbon Estimation Of Harvest Volumementioning

confidence: 99%

“…* Total biomass of harvested trees including below-ground biomass. In both cases, the above-ground biomass is calculated as the product of above ground stem volume and base density of harvested tree species and then adding crown biomass using the proportion suggested by earlier studies [31,35] for Nepal and [44] for Queensland. Below-ground biomass is estimated as 25% of the stem biomass considering 0.25 root shoot ratio [59] for Nepal whereas it is taken as 0.26 for the Spotted gum in Queensland [46].…”

Section: Stock and Recovery Of Biomass And Carbon In Product Harvestingmentioning

confidence: 99%

“…The highest figure for damage to seedlings and saplings in these sites is associated with a higher level of regeneration in the harvested area. Nepal had an average of 21,649 seedlings and 1662 saplings per ha [31] whereas Queensland Spotted gum-dominated native forests hosted up to 2500 regenerating stems per ha [81]. The larger trees and minimum regeneration supported minimal damage to the undergrowth and neighbouring trees [53], whereas in Nepal, the reverse applied with higher regeneration and wider variance in harvested tree size (28-56 cm in DBH and 8-30 m in height).…”

Section: 5% This Studymentioning

confidence: 99%

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Implications of Selective Harvesting of Natural Forests for Forest Product Recovery and Forest Carbon Emissions: Cases from Tarai Nepal and Queensland Australia

Poudyal

Maraseni

Cockfield

2019

Forests

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Selective logging is one of the main natural forest harvesting approaches worldwide and contributes nearly 15% of global timber needs. However, there are increasing concerns that ongoing selective logging practices have led to decreased forest product supply, increased forest degradation, and contributed to forest based carbon emissions. Taking cases of natural forest harvesting practices from the Tarai region of Nepal and Queensland Australia, this study assesses forest product recovery and associated carbon emissions along the timber production chain. Field measurements and product flow analysis of 127 commercially harvested trees up to the exit gate of sawmills and interaction with sawmill owners and forest managers reveal that: (1) Queensland selective logging has less volume recovery (52.8%) compared to Nepal (94.5%) leaving significant utilizable volume in the forest, (2) Stump volume represents 5.5% of total timber volume in Nepal and 3.9% in Queensland with an average stump height of 43.3 cm and 40.1 cm in Nepal and Queensland respectively, (3) Average sawn timber output from the harvested logs is 36.3% in Queensland against 61% in Nepal, (4) Nepal and Queensland leave 0.186 Mg C m−3 and 0.718 Mg C m−3 on the forest floor respectively, (5) Each harvested tree damages an average of five plant species in Nepal and four in Queensland predominantly seedlings in both sites, and (6) Overall logging related total emissions in Queensland are more than double (1.099 Mg C m−3) those in Nepal (0.488 Mg C m−3). We compared these results with past studies and speculated on possible reasons for and potential implications of these results for sustainable forest management and reducing emissions from deforestation and forest degradation.

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The role of affluence, urbanization, and human capital for sustainable forest management in China: Robust findings from a new method of Fourier cointegration

Yılancı

Ulucak²,

Zhang

et al. 2022

Sustainable Development

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Affluence and planned urbanization may have a crucial role in conserving forests and decreasing forest footprint with rising awareness and human development. Productivity rise from technological progress is key to facilitating the underlying mechanisms of theoretically expected changes in all those processes. They are seen as an alternative way to transform the current habits into one that is conservative and respectful to the environment while keeping the economic welfare at the same time. By following the theoretical underpinnings of such expectations, this article investigates how the development changes of China have impacted on the forest footprint. In this frame, the study is an attempt to empirically inquire underlying mechanisms of the forest transition hypothesis, which supports the idea that affluence, urbanization, human capital, and productivity can help to save forests. The transition process is depicted by a hump-shaped curve mostly attributed to the Environmental Kuznets Curve in the literature. The period 1961-2017 is particularly relevant as it precedes and follows the Chinese open-door policy of the 1980s. This study reaches robust findings and new insights for sustainable forest management. Results show that income growth did not contribute to reducing the forest footprint, as the forest footprint has increased with income rises. On the contrary, urbanization, human capital, and total factor productivity have reduced the forest footprint. Based on the evidence provided, policymakers should devote increasing attention to education that serves human capital formation, and efficiency gains for sustainable forestry simultaneously.

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Estimating potential harvestable biomass for bioenergy from sustainably managed private native forests in Southeast Queensland, Australia

Cited by 15 publications

References 27 publications

A Review on the Potential of Forest Biomass for Bioenergy in Australia

A Review on the Potential of Forest Biomass for Bioenergy in Australia

Implications of Selective Harvesting of Natural Forests for Forest Product Recovery and Forest Carbon Emissions: Cases from Tarai Nepal and Queensland Australia

The role of affluence, urbanization, and human capital for sustainable forest management in China: Robust findings from a new method of Fourier cointegration

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