Embodiment Analysis for Greenhouse Gas Emissions by Chinese Economy Based on Global Thermodynamic Potentials

This paper considers the Global Thermodynamic Potential (GTP) indicator to perform a unified assessment of greenhouse gas (GHG) emissions, and to systematically reveal the emission embodiment in the production, consumption, and international trade of the Chinese economy in 2007 as the most recent year available with input-output table and updated inventory data. The results show that the estimated total direct GHG emissions by the Chinese economy in 2007 amount to 10,657.5 Mt CO 2-eq by the GTPs with 40.6% from CH 4 emissions in magnitude of the same importance as CO 2 emissions. The five sectors of Electric Power/Steam and Hot Water Production and Supply, Smelting and Pressing of Ferrous and Nonferrous Metals, Nonmetal Mineral Products, Agriculture, and Coal Mining and Dressing, are responsible for 83.3% of the total GHG emissions with different emission structures. The demands of coal and coal-electricity determine the structure of emission embodiment to an essential extent. The Construction sector holds the top GHG emissions embodied in both domestic production and domestic consumption. The GHG emission embodied in gross capital formation is more than those in other components of final demand characterized by extensive investment and limited household consumption. China is a net exporter of embodied GHG emissions, with a remarkable share of direct emission induced by international trade, such as textile products, industrial raw materials, and primary machinery and equipment products exports. The fractions of CH 4 in the component of embodied GHG emissions in the final demand are much greater than those 1898 fractions calculated by the Global Warming Potentials, which highlight the importance of CH 4 emissions for the case of China and indicate the essential effect of CH 4 emissions on global climate change. To understand the full context to achieve GHG emission mitigation, this study provides a new insight to address China's GHG emissions status and hidden emission information induced by the final demand to the related policy-makers.


Introduction
China has been considered as the largest carbon dioxide emitter in the World since 2007 [1].Certainly, along with the consumption structure upgrade and urbanization in the future, the amount of GHG emissions in China is expected to increase further [2].All these facts reflect the unprecedented emergency of GHG emission control and mitigation in the Chinese economy.Before any effective mitigation measures can be undertaken, a clear understanding of the current emission status and situation must be obtained first.In addition to the direct GHG emission mitigation for prominent industries, there is also a need to make policies by identifying the consumption-side mitigation polices that the emissions induced by the final demand [3,4].
To quantify and evaluate GHG emission patterns and structure for a society, only a small number of economic sectors considered are limited to reflect more detailed and complex network structure.As a commonly available economic model to describe the complicated network relationship and structure of economic sectors, input-output model originally introduced by Leontief to analyze the interdependence of economic sectors has been rigorously extended and widely used in the sectoral embodiment analysis of GHG emissions in general (e.g., [4][5][6]).The concept of embodied emissions facilitates a deeper appreciation of the sectoral total emission requirements in terms of both the direct, visible and indirect, hidden emission cost, which appreciates the industry-specific features as well as the holistic societal structure.Extensive studies have been made to perform input-output analysis of GHG emissions in China, mainly focusing on CO 2 emission embodiment (e.g., [7][8][9][10][11][12][13][14][15][16]).The unique official GHG emission inventory of China pointed out that CH 4 emissions accounted for 19.4% of the total national-wide GHG emissions in terms of CO 2 , CH 4 and N 2 O in 1994 [17].Zhang and Chen [18] reported that the total CH 4 emission of 26 industrial sectors by Chinese economy in 2007 is 39,592.7 Gg or 989.8 Mt CO 2 -eq by the lower referred IPCC global warming potential (GWP), in magnitude of about one sixth of China's CO 2 emission from fuel combustion and greater than CO 2 emissions from fuel combustion of many economically developed countries such as UK, Canada, and Germany.Only considering the CO 2 emissions cannot reflect the real situation and full-scale picture of China's GHG emissions, especially in terms of sectoral structure and embodiment in final consumption and international trade [3].Prominent studies about the embodiment of China's GHG emissions were systematically conducted by Chen and co-workers in their multi-scale ecological input-output analysis (IOA) of environmental emissions.In his doctoral dissertation Zhou [19] presented two sets of databases for embodiment intensity of GHG emissions, one for the Chinese economy in 1992 under the Material Product System (MPS) for planning economies of the Soviet socialist style and another for the Chinese economy in 2002 under the System of National Accounts (SNA) for marketing economies; Chen et al. [20] and Chen and Chen [21] afterwards accounted for the GHG emission embodiment in the Chinese economy in 2005 and 2007, respectively; Chen and Chen [22] simulated the GHG emission embodiment in the global economy 2000, referring to Chinese economy; in particular, Chen and Zhang [3] provided a concrete GHG emission inventory of Chinese economy 2007 to cover all the main anthropogenic sources of CO 2 , CH 4 and N 2 O, and presented a detailed input-output analysis for the GHG emission embodiment in final consumption and international trade.These studies have contributed to direct and indirect GHG emission estimation and related assessment for mitigation potential in China.
It is worth noting that in order to account for the equivalent CO 2 (CO 2 -eq.) emissions, one typical scheme has been applied extensively in most previous studies, which is based on the commonly referred IPCC Global Warming Potentials (GWPs) over a time horizon of 100 years.In fact, the indicator of GWP based on simplified radiation models has various GWP values over different time horizons even for the same greenhouse gas [23].Furthermore, the GWP indicator is merely one kind of evaluation method for GHG emissions.There are several other typical equivalent indicators based on different evaluation models to assess GHG emissions.The Global Thermodynamic Potential (GTP) indicator derived from chemical exergy model is one option, which has been gradually accepted as a unified measure for GHG emissions in recent years.
Defined as the maximum amount of work which can be produced by a system as it comes to equilibrium with a reference environment [24][25][26] to represent the physical deviation between the system and the reference environment, the concept of exergy based on the first two laws of thermodynamics provides us with an ideal unified measure for various environmental emissions as a consistent and objective assessment [27][28][29][30][31][32].All emissions have definable, calculable and additive exergy contents with respect to the defined reference environment.Wall [24,33] further suggested exergy as a suitable measure of environmental impact of waste emissions and asserted that all utilization of resources and disposal of waste products affect nature and the effect is strongly related to the amount of exergy in the utilized resource or the disposed waste [34].Ayres [35] stated that non-zero exergy can be regarded as the potential for doing harm by driving uncontrolled reaction in the environment.Rosen and his colleagues [25,27,[36][37][38][39] have illustrated the meaning of exergy to environmental emissions.The total exergy of an emission is the physicochemical work absorbed by the environment in order to equilibrate the substances of the emission with the standard environment [31].In other words, the exergy emitted represents a driving potential, hence causing environmental damage, particularly when released on a large scale into the environment [27,33,40].With the global reference environment model initiated by Szargut [28], exergy has been taken as a physical indicator for the potential environmental effect on the biophysical earth in general and geochemical sphere in particular [28,29].Exergy-based unifying assessment for the environmental emissions of typical social sectors [30,34,41] and social systems [42][43][44] has been extensively performed in recent years.Furthermore, the indicator of Global Thermodynamic Potentials based on the chemical exergy model has been used to compare the thermodynamic departure between the GHG emission and its surrounding relative to carbon dioxide in terms of carbon dioxide equivalents [18,21,22,44].
Rational and significant evaluation for environmental emissions from different angles of view can be carried out based on single or multi-disciplinary evaluation methods [45].Besides the emission embodiment based on the GWPs, further research coupled with other emission equivalent evaluation will provide a more sound theoretical basis for making and analyzing GHG emission embodiment for the Chinese economy.The target of this paper is to consider the Global Thermodynamic Potential indicator to perform a unified GTP-based emission assessment of the three most commonly considered GHGs, i.e., CO 2 , CH 4 and N 2 O, and to systematically reveal the emission embodiment in production, consumption, and international trade of the Chinese economy in 2007 as the most recent year with available input-output tables and updated inventory data.
The main context of this paper is organized as follows.In Section 2, we describe the GTP calculation methodology, input-output analysis, and data sources.Section 3 and Section 4 present the direct GHG emission and embodied GHG emission analysis, respectively, and corresponding analysis results are discussed.Finally, main conclusions will be drawn in Section 5.

Global Thermodynamic Potentials
Due to the emissions being in disequilibrium with the reference environment, GHG emissions have an exergy value.As to the emission account for the society system as a macro-economy, it is reasonable to adopt a global standard environment model to resemble the atmosphere, the ocean and the Earth's upper crust with average geophysical chemical characteristics as the reference environment [28,46].The chemical exergy of an emission reflects the deviation in chemical composition from the reference environment, and is the most important contribution to its exergetic value.Therefore, only chemical exergy is considered in this study.The standard chemical exergy values of the basic chemical compound can be readily obtained from Szargut [28] and then the Global Thermodynamic Potential (GTP) of GHG emissions relative to that of carbon dioxide (whose GTP is by definition 1) can be calculated.Detailed exergy factors and corresponding GTPs of CO 2 , CH 4 and N 2 O are listed in Table 1.From the exergetic perspectives, higher exergetic value or GTP of the emission reflects the larger deviation in chemical composition from the reference environment and indicates its essential effect on global climate change.

Input-Output Analysis and Data Sources
The algorithms for input-output analysis and basic embodied emissions have been introduced in detail in [18].Briefly, the emissions generated in both homeland and imports induced by the final demand can be obtained by pre-multiplying the final demand by the row vector of the embodied emission intensity (the multiplication of the direct emission intensity matrix and the well-known Leontief inverse matrix).Then, the embodied emission induced by each category of final demand, such as household consumption, government consumption, and capital investment can be calculated.The emission embodied in domestic production, denoted by EEP, is the emission induced by the final demand minus the emission embodied in imports.The emission embodied in exports (EEE) or imports (EEI; Emission avoided by import in deed) can be calculated by multiplying the embodied emission intensity in terms of a row vector with the exported or imported products (monetary value).The emission embodied in domestic consumption, EEC, represents the production-based emission excluding the emission embodied in exports but including the emission embodied in imports.Combining the embodied emissions from exports and imports or domestic production and domestic consumption, the net embodied emission of international trade balance (EEB) can be obtained.A positive EEB means the net embodied emission exporter or a trade surplus of embodied emission, and negative means the net embodied emission importer or deficit.Concrete elaboration of the input-output model and indicator description can be referred to [18].
The Chinese input-output (IO) table of 2007, covering 42 sectors in total [47], is the most recently available IO table.To comply with relevant environmental resources and energy statistics data, Chen and Zhang [3]   For greenhouse gas emissions by the Chinese economy in 2007, an updated concrete inventory covering three of the most concerned types, i.e., CO 2 , CH 4 , and N 2 O, has been compiled by Zhang [48].Using his inventory data, corresponding equivalent values of the three main greenhouse gases by sector can be gained to make a unified assessment.

Direct GHG Emissions
Based on the Global Thermodynamic Potentials (CO 2 :CH 4 :N 2 O=1:115.51:5.33),direct GHG emissions by emission type and sector category are calculated and shown in Table 3  As to the CO 2 emissions, direct emission of Sector 22 (Electric Power/Steam and Hot Water Production and Supply) amounts to 2736.9 Mt, up to 43.3% of the total, followed by those of Sector 14 (Smelting and Pressing of Ferrous and Nonferrous Metals) and Sector 13 (Nonmetal Mineral Products), accounting for 16.3% and 16.2%, respectively.Sector 2 (Coal Mining and Dressing) accounts for 47.0% of the total CH 4 emissions, followed by Sector 1 (Agriculture) for 42.3%.Sector 1 (Agriculture) is also the leading N 2 O emission sector, accounting for 82.4% of the total N 2 O emissions, followed by Sector 12 (Chemical Products Related Industry) for 9.6%, and Sector 22 for 5.4%.
In total the five sectors numbered 1, 2, 13, 14 and 22 are responsible for 83.3% of the total GHG emissions.Among these five sectors, Sector 22 is the largest emitter, with 25.7% of the total GHG emissions, mainly due to massive CO 2 emissions from coal combustion to produce electricity.Owing to their massive CH 4 emissions and the higher GTP 115.51 in comparison with 1 to CO 2 , Sectors 1 and 2 contribute 18.2% and 20.0% of the total GHG emissions, respectively.Owing to massive CO 2 emissions from industrial processes, Sector 14 and Sector 13 contribute 9.7% and 9.6% of the total GHG emissions, respectively.
Direct emission intensity indicates the direct emission per RMB Yuan of industrial output.As shown in Figure 1, the direct GHG emission intensity of Sector 2 (2204.5 g CO 2 -eq/Yuan) is much larger than those of the other sectors, owing to its high CH 4 emission intensity.Prominently, CO 2 emissions from fuel combustion dominate the direct GHG emission intensity of Sector 22, which has a direct emission intensity of 870.8 g CO 2 -eq/Yuan, only less than that of Sector 2. Sector 13 represents another pattern for high direct GHG emission intensity due to its massive CO 2 emissions from industrial processes, with a direct GHG emission intensity of 450.8 g CO 2 -eq/Yuan.CH 4 emissions are the main emission type in Sector 1, which has a direct GHG emission intensity of 397.5 g CO 2 -eq/Yuan.

Embodied Emission Intensities
As shown in Figure 2 for the embodied GHG emission intensities of the 26 sectors in Chinese economy 2007, Sector 2 (Coal Mining and Dressing) holds the top volume of 2781.5 g CO 2 -eq/Yuan (mainly owing to the high direct emission intensity), followed by Sector 22 (Electric Power/Steam and Hot Water Production and Supply) and Sector 13 (Nonmetal Mineral Products) of 1974.7 and 1095.4 g CO 2 -eq/Yuan, respectively, with comparable direct and indirect emission intensities.For all the other sectors except Sector 1, the direct intensity is notably less than the indirect intensity.More evidently, for the 17 sectors numbered 4-10, 15-21, 23, 25 and 26, the embodied intensity is basically induced by indirect emissions due to inter-industrial input, with no remarkable direct emissions.Therefore, the picture of systems embodied emissions as reflected by the input-output model is quite different from that of the direct end emissions [3,6].
The embodied GHG emission intensity can be further divided by the emission type.Figure 3 further presents the emission component of the embodied GHG emission intensity by sector.CO 2 emissions from fuel combustion comprise about one half of GHG emissions in most manufacturing and service sectors.The shares of CO 2 emission (fuel combustion) intensities are especially high in Sectors 3-5, 22 and 24.CO 2 emissions from industrial processes share important proportions in some manufacturing industries such as Sectors 13, 14 and 23.In contrast, non-CO 2 emissions account for about 40%-60% of the total GHG emission intensities in Sectors 1, 2, 6-12, 25 and 26.Embodied GHG emission intensities of Sectors 1, 2 and 6 are dominated by the embodied CH 4 emission intensity.Figure 4 shows the contribution of the direct CH 4 emissions from coal mining in Sector 2 (Coal Mining and Dressing) and CO 2 emissions from fuel combustion in Sector 22 (Electric Power/Steam and Hot Water Production and Supply) to the embodied GHG emission intensity by sector.Around 40-60% of the embodied GHG emission intensities of most manufacturing and service sectors can be derived from these direct emissions.This is due to China's coal-dominated energy structure and coal-dominated electricity system.In 2007, 69.5% of total energy use and 82.9% of total electricity output are coal based [49].Therefore, a large fraction of embodied emissions in final demand sources from coal-consumption economy in China.

Emissions Embodied in Final Consumption
The total GHG emission embodied in domestic production (EEP) and that embodied in domestic consumption (EEC) are accounted as 10,657.5 and 9840.6 Mt CO 2 -eq, respectively.The EEP exceeds the EEC by 8.3%.As shown in Figure 5 for the distribution of GHG emissions embodied in domestic consumption (EEC), Sector 23 (Construction) holds the top embodied GHG emission.China's rapidly expanding infrastructure construction has a significant impact on embodied GHG emissions, as construction activities need a great deal of direct and indirect industrial inputs (e.g., cement, electricity and metal products).Jiang and Tovey [50] reported that the direct and indirect embedded energy use by China's building sector accounts for about one quarter of the total energy use in China.Other sectors such as Sector 26 (Other Service Activities), Sector 1 (Agriculture), Sector 6 (Food Processing, Food Production, Beverage Production, and Tobacco Processing), Sector 16 (Ordinary Machinery, Equipment for Special Purpose), and Sector 17 (Transportation Equipment), which have prominent peaks on emissions embodied in both domestic production and domestic consumption, are either directly involved in manufacturing and processing of raw materials or major consumers of industrial products.Particularly, Sectors 1 and 6 show massive embodied CH 4 emissions due to the increased grain and meat production to meet the rising standard of living level and westernized lifestyle in China's households [3].Table 4 illustrates the economy-wide balance of monetary flows, GHG emissions, CO 2 emissions, and CH 4 emissions.In the whole, household consumption is responsible for 27.5% of the total GHG emission embodied in the final demand.The embodied GHG emission in urban consumption is 2.7 times of that in rural consumption.It is noted that rural and urban consumptions are CH 4 emission intensive.The CH 4 emissions comprise 57.3% of the total embodied GHG emission for the rural consumption and 48.6% for the urban consumption.This can be explained by the main consumption of agricultural products and foodstuff in households.
Prominently, gross capital formation is responsible for 39.0% and 44.3% of the total GHG and CO 2 emission embodied in final demand, respectively, larger than other final demand categories.Weber et al. [12] estimated that capital investment was responsible for 37% of China's CO 2 emissions in 2005.From the three components of GDP by expenditure approach during 2001-2007 (Table 5) [49], two economic components (final consumption expenditure and gross capital formation) shared the majority proportion of the GDP.China has now one of the highest investment rates in the world with the gross capital formation rate in GDP keeping on about 42% in recent years.Capital investments such as in manufacturing, infrastructure, and real estate related sectors have become an important motor for economic growth [8,49], which result in increasing embodied GHG emissions through the demand of electricity, cement, steel, nonferrous metals, etc.Among different final use categories, the shares of imports, gross capital formation and exports in GHG emissions are higher than those in monetary flows, as shown in Table 4, due to the higher emission embodiment.Note: Gross capital formation rate refers to gross capital formation as percentage of gross domestic product by expenditure approach; final consumption rate refers to final consumption expenditures as percentage of gross domestic product by expenditure approach.

Emissions Embodied in International Trade
As shown in Figure 6, the GHG emission embodied in China's exports (EEE) is calculated as 4232.9Mt CO 2 -eq, in magnitude up to 39.7% of the total direct domestic emission.Of the total EEE, 47.8% is due to the CO 2 emission from fuel combustion (2021.7 Mt), 37.1% due to the CH 4 emission, and 15.1% due to the CO 2 emission from industrial processes.Meanwhile, China also avoids emitting 3416.0Mt CO 2 -eq GHGs (EAI or EEI in this paper) as a result of importing goods from the rest of the world.As a net exporter of embodied GHG emissions, the net embodied GHG emission of international trade balance (EEB) is around 816.9 Mt CO 2 -eq.Many authors have addressed the fact that the assumptions regarding the emissions of imports can potentially have a significant impact on the estimate of emission embodiment [51,52].Since the calculation of the GHG emissions embodied in import is based on the assumptions that the imported products have the same emission intensities as those produced in China, it may result in the volume of the real GHG emissions embodied in import (EEI) lower than the result calculated from above assumption.In fact, Chinese industry has the greater relative carbon intensity, through its greater use of coal and less efficient manufacturing methods compared with the trade partners [53][54][55][56].The quantity of embodied GHG emissions in China is greater than the embodied emissions required to manufacture the same goods in the imported countries.According to Yan and Yang [56], CO 2 emissions embodied in China's export were 2.9 times of that embodied in China's import by using American domestic emission factors for the imports.Using the estimated emission factor for each country, OECD [51] derived that the emissions embodied in China's exports were about 4.5 times of those embodied in China's imports in 1997.Peters and Hertwich [57] and Lin and Sun [58] reported that using individual emission factors of the importers, the CO 2 emissions embodied in China's imports would be around four times lower than using China's domestic emission factors.With a relatively high domestic GHG emissions factor in China, actually, net embodied GHG emissions of China's trade balance (EEB) should be larger than the calculated result in this study.
On the sectoral basis, Table 6 shows the distribution of GHG emissions embodied in exports (EEE) and imports (EEI) by sector.The largest GHGs-export sector is Sector 19 (Electronic and Telecommunications Equipment) with 17.8% of the total EEE, followed by Sector 12 (Chemical Products Related Industry, 9.8%), Sector 14 (Smelting and Pressing of Ferrous and Nonferrous Metals, 9.3% of the total), Sector 7 (Textile, 9.0%), Sector 18 (Electric Equipment and Machinery, 7.9%), and other manufacturing industries.As to the distribution of the net embodied GHG emission of international trade balance (EEB) by sector, Sector 7 is the largest net embodied GHG-export sector, accounting for 41.8% of the total EEB, followed by Sector 8 (Garments and Other Fiber Products, Leather, Furs, Down and Related Products, 22.3%), Sector 19 (21.9%),Sector 15 (Metal Products, 20.5%), Sector 18 (20.2%),and Sector 13 (14.8%).In contrast, Sector 3 (Petroleum and Natural Gas Extraction) and Sector 4 (Ferrous and Nonferrous Metals Mining and Dressing) are the top two sectors of net embodied GHG emission importers.It is well known that the total domestic outputs of crude oil, iron ore and some other materials in China cannot satisfy the domestic production demand.

Conclusions
To understand the full context to achieve GHG emission mitigation, embodiment analyses from different angles of view are an important step in evaluating the complex interactions and the likely impact of the whole process on the social network and addressing the mitigation potential of GHG emissions at different points in the socio-economic system before meaningful strategies are recommended.In this paper, considering the Global Thermodynamic Potential indicator to perform a unified GTP-based assessment of GHG emissions provides a new insight to examine the results of GHG emission embodiment for China.The major conclusions are as follows: (1) The estimated total direct GHG emissions by the Chinese economy in 2007 amount to 10,657.(3) China is a net exporter of embodied GHG emissions, with a remarkable share of direct emission induced by international trade.The amount of GHG emissions embodied in China's exports (EEE) is equal to 39.7% of the total direct domestic emission.Of the total EEE, 47.8% is due to the CO 2 emission from fuel combustion, 37.1% due to CH 4 emission, and 15.1% due to the CO 2 emissions from industrial processes.China also avoids emitting 3416.0Mt CO 2 -eq GHGs as a result of importing goods from the rest of the World.In international trade balance, China's textile products, industrial raw materials, and primary machinery and equipment products exports have a significant impact on embodied GHG emissions.(4) Although the main conclusions of GHG emission embodiment based on Global Thermodynamic Potential (GTP) equivalent are similar to those based on Global Warming Potential (GWP) equivalent, CH 4 emissions based on GTP equivalent have remarkable influence in the structure of embodied GHG emissions in the final demand.For instance, CH 4 emissions comprise 57.3%, 48.6%, 39.6%, 31.4% and 37.1% of the total embodied GHG emission for the rural consumption, urban consumption, government consumption, gross capital formation, and exports, respectively, much greater than corresponding fractions calculated based on the GWP in [3].These results highlight the importance of CH 4 emissions for the case of China and indicate the essential effect of CH 4 emissions on global climate change.

Figure 1 .
Figure 1.Direct GHG emission intensities by emission type.

Figure 3 .
Figure 3. Emission component of the embodied GHG emission intensity by sector.

Figure 6 .
Figure 6.GHG emissions embodied in production, consumption and international trade.

Table 2 .
merged these 42 sectors into 26 sectors to compose a revised input-output table for the 2007 Chinese economy.This paper adopts this aggregated IO table directly with sector information listed in Table2.Aggregated sectors for input-output analysis.

Table 3 .
. The estimated total direct GHG emissions by the Chinese economy in 2007 amount to 10,657.5 Mt CO 2 -eq, of which the CO 2 emission contributes 6324.4Mt, CH 4 4328.8Mt, and N 2 O 4.25 Mt.As to the emission structure, CO 2 emissions from fuel combustion comprise 44.34%, CO 2 emissions from industrial process 15.00%, CH 4 emissions 40.62% and N 2 O emissions 0.04%.The CH 4 emissions are in magnitude of the same importance as the CO 2 emissions.GTP-based GHG emissions by Chinese economy 2007 by sector (Mt CO 2 -eq).
Contribution of direct CH 4 emissions from coal mining in Sector 2 and CO 2 emissions from fuel combustion in Sector 22 to the embodied GHG emission intensity by sector.

Table 4 .
Economy-wide balance of monetary and emission flows.

Table 5 .
Gross domestic product (GDP) by expenditure approach.

Table 6 .
Distribution of embodied GHG emissions in international trade by sector.
5 Mt CO 2 -eq by the Global Thermodynamic Potentials with 40.6% from CH 4 emissions in magnitude of the same importance as CO 2 emissions.On a sectoral basis, the five primary sectors of the Electric Power/Steam and Hot Water Production and Supply, Coal Mining and Dressing, Agriculture, Smelting and Pressing of Ferrous and Nonferrous Metals, and Nonmetal Mineral Products are responsible for 83.3% of the total GHG emissions with different GHG emission structures.(2) The demands of coal and coal-electricity determine the structure of emission embodiment to an essential extent.Embodied GHG emission intensities in most manufacturing and service sectors are highly related to the direct CH 4 emissions from coal mining in the Coal Mining and Dressing sector and CO 2 emissions from fuel combustion in the Electric Power/Steam and Hot Water Production and Supply sector.The Construction sector holds the top GHG emissions embodied in both domestic production and domestic consumption.Household consumption which is CH 4 emission intensive to some extent is responsible for 27.5% of the total GHG emission embodied in the final demand.However, the GHG emission embodied in gross capital formation is the largest in the final demand categories.Extensive investment and limited consumption by Chinese economy can be partly reflected by the profile of GHG emission embodiment.