Improving Carbon Stock Estimates for In-Use Harvested Wood Products by Linking Production and Consumption—A Global Case Study

Zhang, Xiaobiao; Chen, Jiaxin; Dias, Ana Cláudia; Yang, Hongqiang

doi:10.1021/acs.est.9b05721

Cited by 38 publications

(28 citation statements)

References 44 publications

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“…The global power consumption of fossil fuels is known to be equal to

In columns 6 and 7, energy consumption of plant biomass is considered with energy content

J kg

and global store of the order of

kg [ 46 ] assuming most land ecosystems are disturbed; fires consume 2 GtC yr

[ 47 ], which constitutes 4% of primary productivity on land 56 GtC yr

[ 48 ] (

W), which amounts to

W globally or

W m

for land on average. Wood consumption due to logging consumes globally about 0.3 GtC yr

[ 49 ]; however, in many regions of the world, logging facilitates forest fires [ 47 , 50 , 51 , 52 ]. Instantaneous power for forest fire is estimated as the power of blackbody radiation at 800 K as

W m

.…”

Section: Figurementioning

confidence: 99%

Life’s Energy and Information: Contrasting Evolution of Volume- versus Surface-Specific Rates of Energy Consumption

Makarieva

Nefiodov

2020

Entropy

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As humanity struggles to find a path to resilience amidst global change vagaries, understanding organizing principles of living systems as the pillar for human existence is rapidly growing in importance. However, finding quantitative definitions for order, complexity, information and functionality of living systems remains a challenge. Here, we review and develop insights into this problem from the concept of the biotic regulation of the environment developed by Victor Gorshkov (1935–2019). Life’s extraordinary persistence—despite being a strongly non-equilibrium process—requires a quantum-classical duality: the program of life is written in molecules and thus can be copied without information loss, while life’s interaction with its non-equilibrium environment is performed by macroscopic classical objects (living individuals) that age. Life’s key energetic parameter, the volume-specific rate of energy consumption, is maintained within universal limits by most life forms. Contrary to previous suggestions, it cannot serve as a proxy for “evolutionary progress”. In contrast, ecosystem-level surface-specific energy consumption declines with growing animal body size in stable ecosystems. High consumption by big animals is associated with instability. We suggest that the evolutionary increase in body size may represent a spontaneous loss of information about environmental regulation, a manifestation of life’s algorithm ageing as a whole.

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“…The global power consumption of fossil fuels is known to be equal to

In columns 6 and 7, energy consumption of plant biomass is considered with energy content

J kg

and global store of the order of

kg [ 46 ] assuming most land ecosystems are disturbed; fires consume 2 GtC yr

[ 47 ], which constitutes 4% of primary productivity on land 56 GtC yr

[ 48 ] (

W), which amounts to

W globally or

W m

for land on average. Wood consumption due to logging consumes globally about 0.3 GtC yr

[ 49 ]; however, in many regions of the world, logging facilitates forest fires [ 47 , 50 , 51 , 52 ]. Instantaneous power for forest fire is estimated as the power of blackbody radiation at 800 K as

W m

.…”

Section: Figurementioning

confidence: 99%

Life’s Energy and Information: Contrasting Evolution of Volume- versus Surface-Specific Rates of Energy Consumption

Makarieva

Nefiodov

2020

Entropy

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“…Despite these shortcomings it has been the most commonly used approach to assess HWP carbon stock in the last decade. Evidently, estimating HWP stocks is challenging and induces uncertainties, because the import and export of wood, as well as inherited emissions from the HWP stock before the modeling period, have to be dealt with (Pukkala 2014;Zhang et al 2020;Yang and Zhang 2016). In contrast to a country specific carbon balance, where HWP carbon stocks are needed to correctly allocate climate impacts, the calculation of RDFs does not require them.…”

Section: Required Displacement Factors For Comparing the Climate Bene...mentioning

confidence: 99%

Required displacement factors for evaluating and comparing climate impacts of intensive and extensive forestry in Germany

Buschbeck

Pauliuk

2022

Preprint

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Background Forestry plays a major role in climate change mitigation. However, which intensity of logging is best suited for that task, remains controversial. We contribute to the debate by quantitatively analyzing two different forest management scenarios in Germany, an intensive and an extensive one. We assess whether increased carbon storage in wood products and substitution of other emission-intensive materials can offset reduced carbon stocks in the forest due to increased harvesting. For that, we calculate annual Required Displacement Factors (RDF) - a dimensionless quantity that indicates the minimal Displacement Factor (DF) so that intensive forestry outperforms extensive forestry from a climate perspective.ResultAnnual RDFs show values of about 1 in the first two decades and after 2030 a steady decline to about 0. The comparison between current average DF and calculated RDFs indicates that for now, a compensation of lower carbon stocks in forests by material and energy substitution as well as product carbon storage is possible. In the future however, DFs will decline due to a decarbonization of the economy, hence the net climate mitigation potential of substitution diminishes. In terms of total global warming potential, the performance of the two scenarios is likewise dependent on how quickly the rest of the economy decarbonizes: With a conservative estimate on future emission reduction, leading to relatively high DFs, intensive forestry is beneficial, reducing total global warming potential (GWP) over the analysed time period of 40 years by 100 - 300 Mt CO2-equ. compared to extensive forestry. With an optimistic estimate for low future DFs extensive forestry is beneficial, reducing GWP over the same time period by 0 - 200 Mt CO2-equ. compared to intensive forestry.Conclusion Our findings highlight the necessity of a broad systems perspective for assessing the climate impacts of wood use. Robust statements about the climate performance of different forestry scenarios can only be made by including different possible industry decarbonisation pathways into the assessment. Still, we can robustly conclude that the later a change in forest management is initiated, the more beneficial the extensive scenario will be, because carbon displacement diminishes as decarbonization proceeds.

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“…When reporting LULUCF emissions, the long-term carbon stored in wood products is usually either not reported or not accounted for in models that simulate forest land use (Stehfest et al, 2019;Havlík et al, 2011;Braakhekke et al, 2019;Doelman et al, 2018Doelman et al, , 2020Humpenöder et al, 2018). As management of forests and different uses of harvested wood play a crucial role in the regulation of the concentration of atmospheric CO 2 , it is important to account for this pool when reporting LULUCF emissions (IPCC, 2019;Johnston and Radeloff, 2019;Böttcher and Reise, 2020;Zhang et al, 2020).…”

Section: Land-use Change Emissionsmentioning

confidence: 99%

Estimating global land system impacts of timber plantations using MAgPIE 4.3.5

et al. 2021

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Abstract. Out of 1150 Mha (million hectares) of forest designated primarily for production purposes in 2020, plantations accounted for 11 % (131 Mha) of this area and fulfilled more than 33 % of the global industrial roundwood demand. However, adding additional timber plantations to meet increasing timber demand intensifies competition for scarce land resources between different land uses such as food, feed, livestock and timber production. Despite the significance of plantations with respect to roundwood production, their importance in meeting the long-term timber demand and the implications of plantation expansion for overall land-use dynamics have not been studied in detail, in particular regarding the competition for land between agriculture and forestry in existing land-use models. This paper describes the extension of the modular, open-source land system Model of Agricultural Production and its Impact on the Environment (MAgPIE) using a detailed representation of forest land, timber production and timber demand dynamics. These extensions allow for a better understanding of the land-use dynamics (including competition for land) and the associated land-use change emissions of timber production. We show that the spatial cropland patterns differ when timber production is accounted for, indicating that timber plantations compete with cropland for the same scarce land resources. When plantations are established on cropland, it causes cropland expansion and deforestation elsewhere. Using the exogenous extrapolation of historical roundwood production from plantations, future timber demand and plantation rotation lengths, we model the future spatial expansion of forest plantations. As a result of increasing timber demand, we show a 177 % increase in plantation area by the end of the century (+171 Mha in 1995–2100). We also observe (in our model results) that the increasing demand for timber amplifies the scarcity of land, which is indicated by shifting agricultural land-use patterns and increasing yields from cropland compared with a case without forestry. Through the inclusion of new forest plantation and natural forest dynamics, our estimates of land-related CO2 emissions better match with observed data, in particular the gross land-use change emissions and carbon uptake (via regrowth), reflecting higher deforestation with the expansion of managed land and timber production as well as higher regrowth in natural forests and plantations.

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Improving Carbon Stock Estimates for In-Use Harvested Wood Products by Linking Production and Consumption—A Global Case Study

Cited by 38 publications

References 44 publications

Life’s Energy and Information: Contrasting Evolution of Volume- versus Surface-Specific Rates of Energy Consumption

Life’s Energy and Information: Contrasting Evolution of Volume- versus Surface-Specific Rates of Energy Consumption

Required displacement factors for evaluating and comparing climate impacts of intensive and extensive forestry in Germany

Estimating global land system impacts of timber plantations using MAgPIE 4.3.5

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