1. Introduction
Since the beginning of the 21st century, the carbon emissions caused by human activities have increased year by year, which has had many negative effects on the productivity and life of human beings. At present, carbon emissions are a key reason for climate change [
1]. China is not only the largest developing country in the world but also the largest country that emits carbon dioxide [
2]. To reduce the negative impact of global warming and the deterioration of the ecological environment, China, as one of the important member states of the United Nations, at the 2009 Copenhagen Conference, made a commitment to reduce carbon dioxide emissions per unit of Gross Domestic Product (GDP) by 40%–45% from the 2005 level by 2020 [
3]. Afterward, at the Climate Change Conference in Paris in 2016, the Chinese government promised to make carbon dioxide emissions peak by the end of 2030 and to strive to achieve the goal as early as possible. According to the report of the United Nations Intergovernmental Panel on Climate change (IPCC), agricultural production has become the second-largest source of greenhouse gas emissions in the world, accounting for 14% of the world’s greenhouse gas emissions. In addition, agricultural emissions account for 50% of CH
4, 70% of N
2O, and 20% of CO
2 [
4]. Therefore, reducing agricultural carbon emissions, as an important source of greenhouse gas emissions, is essential.
Jilin Province, located in northeast China [
5], is a major agricultural province in China and is located in the world-famous black soil belt. The total amount of cultivated land ranks fifth in the country. According to the Statistical Bulletin on National Economic and Social Development in 2019, the total grain output of Jilin Province reached 38.78 million tons in 2019 and remained at more than 35 million tons for seven consecutive years, ranking first in the country in net increase. Therefore, it is of great significance to China to develop low-carbon agriculture and sustainable agriculture based on relevant studies of existing problems in agricultural carbon emissions in Jilin Province.
The term agricultural carbon emissions is what we refer to as greenhouse gas emission caused directly or indirectly by chemical fertilizers, pesticides, fossil fuels, and waste disposal in the process of agricultural production [
6]. In previous studies, most scholars have estimated agricultural greenhouse gas emissions generally based on Volume 4 of the 2006 IPCC Guidelines on National Greenhouse Gas Inventories [
7,
8,
9,
10,
11]. However, different scholars have different opinions and use different methods of calculating. For example, Bennetzen et al. (2016) [
12] applied the Kaya–Porter identity (KPI) to calculate greenhouse gas emissions from farming and animal husbandry in global agricultural production and predicted possible changes in the future. Peter et al. (2017) [
13] used calculators to assess greenhouse gas emissions from crop cultivation, while Linderholm (2020) [
14] adopted carbon capture Life Cycle Assessment (CC-LCA), an approach that calculates the carbon footprint of agricultural production and the net greenhouse gas emissions of agricultural production, thereby making the scope of consideration more comprehensive.
In recent years, scholars have analyzed greenhouse gas emissions from different perspectives, believing that such emissions are influenced by different carbon emission sources and various factors. On the one hand, many scholars have pointed out that the use of chemicals in agricultural production and life, such as chemical fertilizers, pesticides, and agricultural films, produces certain carbon emissions [
15]. In addition, energy consumption, such as irrigation electricity and fossil fuel combustion, also lead to an increase in carbon emissions [
16]. Furthermore, land-use change also produces a lot of carbon emissions [
17,
18]. On the other hand, rice cultivation; manure of cattle, sheep, goats, pigs, chickens, ducks, and other livestock and poultry; and straw burning are also the main factors that cause carbon emissions in the process of crop production [
9,
19,
20,
21,
22,
23]. Due to the diversity of carbon sources to a certain extent, different scholars have adopted a variety of empirical methods of studying the influential factors. The methods commonly applied are the Kaya identity, the logarithmic mean Divisia index (LMDI) decomposition model, the environmental Kuznets curve (EKC), the co-integration autoregressive distributed lag (ARDL) model, the nonlinear autoregressive distributed lag (NARDL) co-integration technique, the STIRPAT model, the denitrification decomposition (DNDC) online model, and so on [
24,
25,
26,
27,
28,
29]. Due to specific characteristics of the LMDI model, such as reversible factorization, complete decomposition, and no residuals in decomposition results, the LMDI model is the selected model for this paper.
Some of the previous studies were are mainly on how to reduce carbon emissions, a hot topic in the research on the field recently. First, carbon emissions can be reduced by government policies, such as modifying greenhouse gas emission caps, optimizing management practices, increasing carbon taxes, and increasing regulatory efforts [
30,
31,
32]. Second, carbon emissions can be mitigated by using green fertilizers, avoiding crop burning, adjusting the soil’s physical and chemical properties, and minimizing agricultural resource inputs so as to achieve a circular and sustainable ecological environment [
33,
34,
35]. Finally, low-carbon agriculture can be further achieved by adopting conservation tillage, enhancing the use of agricultural input resources, facilitating the optimization and upgrading of the industrial structure, and introducing new technological means such as biochar [
36,
37,
38,
39,
40].
By reviewing the existing literature, many scholars have analyzed the issues related to agricultural carbon emissions from different perspectives. At present, the research on agricultural carbon emissions mainly focuses on the following three aspects: the first is the measurement methods of agricultural carbon emissions, the second is the influential factors in agricultural carbon emissions, and the third is the countermeasures of agricultural carbon emission reduction. There are many studies on carbon emissions at present, but they focus on only one aspect of planting or animal husbandry, and there is a lack of overall research on agricultural carbon emissions in Jilin Province, a major agricultural province in China. Therefore, based on what has been achieved in previous relevant studies so far, this paper takes Jilin Province of China as an example, studies the current situation of agricultural carbon emissions in Jilin Province, and calculates the total carbon emissions from planting and animal husbandry in the 21 years from 1998 to 2018. Additionally, through dynamic analysis of the change characteristics of agricultural carbon emissions, structural changes, agricultural carbon emission intensity, and density, finding out the changes in agricultural carbon emissions. Finally, through the construction of the logarithmic mean Divisia index (LMDI) factor decomposition model, the main driving factors in agricultural carbon emissions in Jilin Province are identified, and relevant suggestions can be put forward on the development of low-carbon agriculture in Jilin Province. Different from all the other studies, the contribution of this study can be seen as follows: First, the research is done by taking both planting and animal husbandry as a new joint basis. Second, this paper is more comprehensive in selecting carbon sources, with fourteen carbon emission sources being included in the collection, which improves the accuracy of agricultural carbon emission measurement. By using the expanded Kaya identity, the influential factors in agricultural carbon emissions are classified as production efficiency factors, economic-level factors, industrial structure factors, and labor factors. Furthermore, the LMDI is applied to investigate the impact of various factors on agricultural carbon emissions. This can be used as a reference for other provinces in China and even the whole world, providing data support and an empirical basis for the formulation of policy recommendations on agricultural carbon emissions in other countries and regions.
2. Materials and Methods
2.1. Data
The samples in the case study of agricultural carbon emissions in the paper are selected from a database between 1998 and 2018, which is 21 years in total. The data of the various indicators analyzed are derived from three different yearbooks: the China Statistical Yearbook, the Jilin Province Statistical Yearbook, and the China Rural Statistical Yearbook. In them, the amounts of chemical fertilizers, pesticides, and agricultural plastic films are what have been actually used in those years. The size of the land plowed is subject to the area sown with crops in the current year. Agricultural irrigation is based on the effective irrigated area in the current year. The sown area of rice is taken as the actual sown area of that year.
2.2. Estimating Agricultural Carbon Emissions
Agricultural carbon emissions are a significant criterion for measuring the level of sustainable agricultural development and low-carbon agriculture. The measurement and calculation of agricultural carbon emissions are mainly based on the carbon emission coefficient method. For the planting industry, carbon emission sources were mainly studied from seven aspects: fertilizers (convert into purity), agricultural diesel fuel, agricultural plastic films, pesticides, land plowing (the real sown area of crops), irrigation, and paddy rice planting.
For animal husbandry, carbon emissions caused by animal intestinal fermentation and manure emissions are also one of the important sources of agricultural carbon emissions (ACE). Carbon emission sources in animal husbandry include cattle, horses, donkeys, mules, goats, sheep, and pigs. In the paper, three different greenhouses gases, CO2, CH4, and N2O, were converted to CO2eq using the global warming potential (GWP) for the convenience of calculation and analysis. Specifically, CO2eq is a unit of measure of different greenhouse gas emissions that can be used to standardize the greenhouse effects of different greenhouse gases, including carbon-based greenhouse gases such as carbon dioxide and methane, and non-carbon greenhouse gases such as nitrous oxide. Therefore, the database for the study is taken from the assessment report of the United Nations Intergovernmental Joint Committee on Climate Change (IPCC), and research on the measurement and calculation of agricultural carbon emissions is uniformly conducted using CO2eq. Therefore, GWP (CO2) = 1, GWP (CH4) = 25, and GWP (N2O) = 298, that is, 1 ton of methane equals 25 tons of carbon dioxide, and 1 ton of nitrous oxide equals 298 tons of carbon dioxide.
2.2.1. Carbon Emission Calculation for the Planting Industry
The carbon emission calculation for the planting industry can be performed using the following Equation (1) based on what Tian and Zhang proposed (2013) [
41]:
where
represents the total agricultural carbon emission,
represents the type of carbon source,
is the carbon emission of the
type of carbon source,
is the used amount of the
type of carbon source, and
is the coefficient of the
type of carbon source.
The carbon emission coefficient of each carbon source is shown in
Table 1. The coefficients are derived from classic studies in the field of natural science (Wu et al., 2002, IPCC 2007, Tian 2013). These studies have been widely accepted and applied, and their accuracy has been recognized as well.
2.2.2. Carbon Emission Calculation for the Animal Industry
According to the IPCC’s Fifth Assessment Report (2014) [
53], the measurement and calculation of agricultural carbon emissions are represented with CO
2eq uniformly, so the calculation of total carbon dioxide emissions in animal husbandry in Jilin Province is as shown in Equation (2):
Methane or N
2O emissions per animal species in Jilin Province are measured as the product of the year-end number of animals (AP; head/year) and their emission factor (EF; kg/unit/year), as shown in Equation (3):
where
represents the amount of methane or nitrous oxide emissions produced by animal husbandry. If
= CH
4, then
represents the methane emissions of different animals. Besides, if
= N
2O, then
represents the nitrous oxide emissions of different animals (unit: 10,000 tons/year).
The carbon source coefficients of various animals in the livestock industry are shown in
Table 2.
2.3. The Intensity and Density of Agricultural Carbon Emissions
The total amount of agricultural carbon emissions in Jilin Province can be calculated based on what is shown above, and the intensity and density of agricultural carbon emissions can be calculated in Jilin Province using Equation (4). The carbon intensity refers to the carbon emissions generated by the growth of the GDP per unit, which is mainly used to evaluate the relevance between economic development and carbon emissions in a region.
where
represents the intensity of agricultural carbon emissions, in unit of tons/ten thousand yuan;
represents the input of seven kinds of supplies, such as fertilizers and agricultural plastic films;
represents the carbon emission coefficient of the
supplies; and
represents the total output value of agriculture and animal husbandry.
What we call the agricultural carbon emission density actually refers to the amount of carbon emissions per unit planting area. The agricultural carbon emission density is calculated by Equation (5).
2.4. Influential Factors in Agricultural Carbon Emissions
Up to now, for research on the influential factors in carbon emissions, decomposition analysis methods have been mostly applied. Decomposition analysis consists of the following two methods: structural decomposition analysis (SDA) and index decomposition analysis (IDA). Compared to the SDA, the IDA’s advantages in practical applications are that it does not require input–output table data but only needs to analyze and add time series data. Therefore, it is more feasible for data collection in the early stage, which is consistent with the research in this paper. What the IDA emphasizes on is to break down target variables into several different combinations of influencer factors for research. The Kaya identity and the LMDI model applied in IDA analysis in this paper will be introduced next.
2.4.1. Kaya Identity
The Kaya identity was originally proposed by the Japanese scholar Yoichi Kaya at the IPCC meeting in 1990. It is mainly used to analyze the degree of correlation between carbon dioxide emissions caused by human activities and the population size, economy, and policy [
54]. At present, the Kaya identity is widely used by researchers in the study of driving factors causing changes in agricultural carbon emissions in different countries and regions. This paper is based on the basic theory of Kaya identities, combined with the reality in Jilin Province, to modify the Kaya identities, as shown in Equation (6):
where
represents agricultural carbon emissions, referring to the total agricultural carbon emissions in Jilin Province;
represents the total output value of agriculture and animal husbandry;
represents the total output value of agriculture, forestry, animal husbandry, and fishery;
represents the total agricultural labor force;
represents agricultural production efficiency indicators;
represents agricultural structural factors;
represents agricultural economic development-level factors; and
represents agricultural labor factors.
2.4.2. LMDI Decomposition Model
As for the LMDI model, its full name is the logarithmic mean Divisia index decomposition method, a kind of IDA index decomposition method. Compared to other index decomposition methods, this method has the advantages of complete decomposition, reversible factor decomposition, no residuals in decomposition results, and zero values allowed in the data. Therefore, it is reasonable and feasible to choose the LMDI model. This paper takes the 1998 data as the base period, based on the research content; sets the total agricultural carbon emissions in the base period as
and the total agricultural carbon emissions in period
as
; and takes the subscript
to represent the overall change. The formula is as follows:
By means of the addition decomposition method, the decomposition of the total effect of changes in agricultural carbon emissions, as shown in Formula (8)
Therefore, the expressions of contribution values of each decomposition factor are
3. Results and Discussion
3.1. Estimation Results and Analysis of Emissions
3.1.1. Analysis of the Dynamic Changes in the Agricultural Carbon Emission Structure
According to Equation (1), the total carbon emissions from the planting industry in Jilin Province were worked out in this study, as shown in
Table 3. Currently, the carbon emissions from the planting industry in Jilin Province are gradually increasing year by year, showing a slowly rising trend, with the emissions increasing from 1.684 million tons in 1998 to 3.4662 million tons in 2018, an increase of 1.7822 million tons, with an average annual growth rate of 3.80%. Judging from the average level over the past 20 years in Jilin Province, the carbon emissions caused by the use of chemical fertilizers are the highest, accounting for 57.61% of the total carbon emissions from the planting industry, and the carbon emissions caused by rice cultivation have increased. The percentages of agricultural diesel, agricultural plastic films, pesticides, land plowing, and effective irrigation were 11.29%, 9.7%, 7.21%, 0.06%, and 0.02%, respectively. The main reason is that since agriculture is the main industry in Jilin Province and rice is regarded as one of the main food crops, the sown area of rice and its corresponding output increase annually with the repaid development of the economy, which causes an increase in carbon emissions.
Based on Equations (2) and (3), the total carbon emissions from animal husbandry in Jilin Province could be worked out, as shown in
Table 4. Animal husbandry is an important source of agricultural carbon emissions in Jilin Province, China. Emissions decreased by 1.637 million tons from 10.2611 million tons in 1998 to 8.6141 million tons in 2018. Especially in recent years, with the widespread use of agricultural machinery and equipment, the number of animals has decreased, which has correspondingly reduced the carbon emissions produced by intestinal fermentation and feces of livestock to a certain extent. At present, methane and nitrous oxide are the two major sources of non-carbon greenhouses in Jilin Province. Among agricultural greenhouse gases in animal husbandry in Jilin Province, CH
4 has the largest proportion, but its proportion is shrinking day by day. The proportion of N
2O is relatively stable. Methane (CH
4) and nitrous oxide (N
2O) account for 65% and 35% of carbon emissions from animal husbandry, respectively. Among them, cattle and sheep account for the largest proportion of carbon emissions caused by intestinal fermentation and fecal management. As for donkeys and mules, since they constitute a smaller proportion of carbon emissions, they are put into one category for study. The average emissions of methane and nitrous oxide from cattle are the highest. However, with the promulgation of national policies and regulations and the consistent adjustment of the industrial structure of animal husbandry, carbon emissions from animal husbandry are showing a decreasing trend.
3.1.2. Analysis of Temporal Variations in Agricultural Carbon Emissions in Jilin Province
In this section, the total agricultural carbon emissions in Jilin Province are worked out by specifying the amount of carbon emissions from both planting and animal industries together, as shown in
Table 5. The total carbon emissions increased from 11.9451 million tons in 1998 to 12.0803 million tons in 2018, an increase of 135,200 tons. There are not many changes shown in the table, but there is still some fluctuation. A peak appears in 2007, with 15.9076 million tons in total carbon emissions. The main reason for this phenomenon may be the rapid development of animal husbandry and the rapid increase in intestinal and fecal emissions from various animals. Therefore, the overall emissions from animal husbandry are much higher than those from farming, among which animal husbandry accounts for more than 70% of the total agricultural carbon emissions.
To more clearly clarify the changes and trends in the total agricultural carbon emissions in Jilin Province of China from 1998 to 2018, according to the calculation results in
Table 3,
Table 4 and
Table 5,
Figure 1 was drawn.
Figure 1 shows changes and trends in agricultural carbon emissions from 1998 to 2018 in Jilin Province. Jilin Province’s total agricultural carbon emission growth can be roughly divided into three stages. The first stage is from 1998 to 2007, which was a period of rapid growth of carbon emissions, with an increase from 11.9451 million tons to 15.9078 million tons, a growth rate of 33.2%, during this period; the highest carbon emissions reached 15,907,800 tons in 2007. It can be seen that at this stage, extensive development was still the main mode in Jilin Province. In the meantime, the central government issued a series of preferential agricultural policies, such as reducing taxes, increasing subsidies, etc., which enhanced the enthusiasm of farmers toward production to a certain extent. It is obvious that the input of agricultural resources, such as fertilizers and pesticides, in the planting industry increased, and the proportion of carbon emissions caused by animal husbandry increased as well, accounting for up to more than 83%. It is also obvious that environmental pollution did not get enough attention, and there was poor awareness of the development of low-carbon agriculture. In the second stage, from 2008 to 2015, agricultural carbon emissions in Jilin Province reached a relatively stable situation, with the overall level increasing slowly, and agricultural carbon emissions increased from 14.362 million tons to 14.9502 million tons, an increase of 0.5882 million tons. The possible reason for this phenomenon was probably rapid development of the planting industry in Jilin Province. The scale of cultivation expanded, but the state and the Jilin provincial government issued a low-carbon development, green development policy at the same time, and people gradually started paying attention to environmental protection. Although the scale of cultivation expanded, the increase in carbon emissions was limited. Carbon emissions from livestock farming also declined, accounting for more than 76% of the total carbon emissions. In the third stage, from 2016 to 2018, there was an overall downward trend on the whole, with the total carbon emissions declining from 14.4697 million tons to 12.0803 million tons, a decrease of 2.3894 million tons, or 16.5%. It can also be seen that the concept and policy of carbon emission reduction achieved certain results.
The conclusion is consistent with Huang (2019) [
9], who found that the total agricultural carbon emissions of 31 provinces and cities in China from 1997 to 2016 showed an upward trend on the whole.
Figure 2 shows the sequential growth rate of total carbon emissions. From the perspective of the sequential growth rate, the growth rate of agricultural carbon emissions in Jilin Province changed by a large margin, and the inter-annual change in the sequential growth rate showed fluctuations. The sequential growth rate reached a maximum of 8.87% in 2001, and in 2017 the sequential growth rate was the lowest in history, at −13.91%. In fact, this is not the first time that a negative value occurred; as early as in 2000, 2002, 2005, and 2008, the sequential growth rate of agricultural carbon emissions was negative, too, and various natural disasters, such as floods, droughts, wind, and hail, led to a significant reduction in the input of agricultural chemicals, thus causing changes in the total agricultural carbon emissions. The sequential growth rate from 2009 to 2018 showed a fluctuating trend. In particular, from 2016 to 2018, the sequential growth rate was negative each year, at −3.21%, −13.91%, and −3.02%, respectively. This implies that such measures worked well in Jilin Province with respect to the development of the agricultural economy and other aspects, the promotion of a policy to return farmlands to forests and grass, and the influence of green development and sustainable development as well. However, given that carbon emissions in Jilin Province are still at a high level overall, the government and the public should continue to focus on carbon emission reduction, which is a necessary condition for the realization of low-carbon agriculture and green agriculture.
3.1.3. Analysis of Dynamic Changes in Agricultural Carbon Emission Intensity and Density
To further study the dynamic changes in agricultural carbon emissions’ intensity and density in Jilin Province, an analysis was performed according to Equations (4) and (5), as shown in
Figure 3.
Figure 3 (left) shows changes in the agricultural carbon emission intensity, and
Figure 3 (right) shows changes in the agricultural carbon emission density. Comparing the carbon emission intensities due to the agricultural modernization of Jilin Province from 1998 to 2018, we observed a volatility trend of first increasingand then decreasing. The carbon emissions declined from 1.84 tons/10,000 yuan in 1998 to 0.61 tons/10,000 yuan in 2018. In 2000, the maximum agricultural carbon emission intensity was 2.08 tons/10,000 yuan. The carbon intensity declined from 2000 to 2015, possibly due to the advances in agricultural technology. In particular, since 2007, the annual carbon emission intensity in Jilin Province has been less than the 20-year average, which also indicates that the low-carbon emission effects in Jilin Province related to agriculture in recent years have been more significant. From the perspective of the agricultural carbon emission density in Jilin Province, we observed an evolutionary process of increasing, decreasing, and then increasing, a trend of fluctuating growth, from 0.41 tons/hectare in 1998 to 0.57 tons/hectare in 2018. In 2013, the agricultural carbon emission density reached the maximum value of 0.59 tons/hectare in the entire research process. The carbon emission density of the planting industry changes with a changing in the crop-planting area, rice-planting area, and total carbon emissions.
The conclusion is consistent with Huang (2019) [
9], who found that the agricultural carbon emission intensity in China showed a downward trend from 1997 to 2016. The above research indicates that the changing trend in the agricultural carbon emission intensity and density in Jilin Province is a typical type of low-intensity, high-density category, which confirms that there is an improvement in the modernization level of agricultural in Jilin Province to a certain extent, promoting the increase in agricultural carbon emissions, and the agricultural carbon emissions may continue to increase in the future with the vigorous promotion of projects of ten billion pounds of grain production in Jilin Province. Therefore, the development of both sustainable agriculture and low-carbon agriculture is the key to the future development of the agricultural industry in Jilin Province.
3.2. Analysis of Influential Factors in Agricultural Carbon Emissions in Jilin Province
According to the LMDI model, the influential factors in agricultural carbon emissions can be analyzed by using Equations (7)–(12). An in-depth analysis of the impacts of various factors contributing to changes in agricultural carbon emissions and the decomposition results of agricultural carbon emissions in Jilin Province are shown in
Table 6. Based on the results of LMDI analysis, the changes in carbon emissions caused by the changes in various influential factors are shown as positive values, indicating that the influential factors have a positive effect on the changes in carbon emissions; on the contrary, if the change in carbon emissions are shown as negative value, indicating that the influencial factors have a negative impact on the change in carbon emissions. Based on what is mentioned above, the results fall into two categories: one is the inhibitory factor of agricultural carbon emissions, and the other is the driving factor of agricultural carbon emissions.
Based on the analysis of the influential factors in agricultural carbon emissions in Jilin Province, and by comparing the results with the conclusion by Tian (2014) [
8], we concluded that efficiency factors, structural factors, and labor factors all suppressed China’s agricultural carbon emissions to a certain degree, while the rapid improvement of the economic level led to a continuous increase in agricultural carbon emissions.
3.2.1. Agricultural Productivity Factors
Agricultural productivity is the most significant factor that curbs agricultural carbon emissions. The effects of production efficiency factors on agricultural carbon emissions in Jilin Province are wholly negative, except for the positive values shown for a few years. This also achieved a cumulative reduction in agricultural carbon emissions in Jilin Province over the past 20 years to 13.4835 million tons, which also implies that assumption that the other three influential factors remain unchanged. There is still some improvement in the agricultural productivity in Jilin Province, a development caused by the advancement in and innovation of scientific and technological knowledge. In addition, the further upgrade in agricultural modernization has facilitated a decrease in carbon emissions in Jilin Province to an average of 0.6742 million tons per year over the past 20 years. This inhibitory effect was the largest in 2008, with a cumulative inhibition of 3.0679 million tons. However, since 2011, the overall degree of inhibition has decreased slightly compared to previous years. This indicates that improving agricultural production conditions and promoting the advancement in agricultural science and technology are necessary to reduce agricultural carbon emissions in Jilin Province, which is one of the key tasks to achieve sustainable development of agriculture in Jilin Province in the future.
3.2.2. Agricultural Industrial Structure Factors
Table 6 indicates that compared to the factors in agricultural productivity and agricultural labor force, the overall degree of inhibition is relatively slight in agricultural industrial structure factors, showing dynamic changes as a whole, with a slight fluctuation of the curve. A total of 778,900 tons of carbon emission reduction has been achieved by agricultural structural factors over the past 20 years, of which 495,900 tons of carbon emissions were inhibited in 2002, reaching a maximum value in history during the research period. Given that other influential factors remain unchanged, an average of 38,900 tons of carbon emission reduction has been achieved each year. Carbon emissions show positive values in some years and negative values in other years. These results also indicate that the agricultural industrial structure of Jilin Province has been in the process of adjustment and transformation to a certain extent, which has led to unstable results of the proportion of the agricultural industrial structure factors in agriculture carbon emissions. The ratio of the total output value of agriculture, forestry, animal husbandry, and fishery in Jilin Province increased from 388.4:10.45:266.84:9.61 in 1999 to 992.96:73.28:1001.64:39.02 in 2018. Although the output value of forestry and fisheries has improved to a certain extent, the agricultural industrial structure of Jilin Province is still dominated by cultivation and animal husbandry, accounting for 45% and 46%, respectively, of the total output value of agriculture, forestry, animal husbandry, and fishery. Therefore, with the promotion of supply structural reforms and the development of sustainable agriculture, there is a need to give full play to the role of cultivation and animal husbandry; further optimize the industrial structure; promote the comprehensive and coordinated development of agriculture, forestry, animal husbandry, and fishery; and explore the new low-carbon agricultural development model of high output and low emissions.
3.2.3. Agricultural Labor Force Factors
The agricultural labor force factor means the degree of change in agricultural carbon emissions caused by an increase or a decrease in the number of agricultural workers. As one of the main kinetic factors in social productivity, agricultural labor force factors have a significant influence on agricultural input, production models, and management and decision making for the agricultural labor force to a large extent. It can be seen from the figure and table that the agricultural labor force factor is the indirect inhibitory factor in the agricultural carbon emissions, and the effect of the inhibitory factor on the growth of carbon emissions lies between the agricultural carbon intensity factors and the agricultural industrial structure factors. In total, 1.5755 million tons of carbon emissions were inhibited from 1999 to 2018, given that other influential factors remained unchanged, that is, an average of 78,800 tons of carbon emissions were inhibited each year. With the increase in urbanization in Jilin Province, the number of agricultural laborers moving to the secondary and tertiary industry has increased as well, and the changing number of employees has reduced the size of the labor force, which can inhibit carbon emissions from the source to a certain extent. In addition, by improving the quality of the agricultural labor force and allowing agricultural practitioners to master knowledge of scientific agricultural management and agriculture-related skills, which improves the agricultural production efficiency, and decreases carbon emissions to a certain extent as well.
3.2.4. Economic Factor
Table 6 indicates that the economic factor is the main driving factor that increases agricultural carbon emissions in Jilin Province. It shows dynamic changes on the whole, with relatively greater fluctuations. It played a role in reducing carbon emissions during 1999–2000, 2015–2016, and 2016–2017 and showed a positive effect in the remaining time periods. It contributed a cumulative total of 15.9659 million tons of carbon emissions in Jilin Province from 1999 to 2018, contributing an average of 0.7983 million tons per year over the past 20 years, while other factors remained unchanged. The contribution reached the maximum value of 2.9528 million tons of carbon emissions from 2003 to 2004. This was mainly due to the implementation of a preferential agricultural policy and an increase in the agricultural income, which increased the enthusiasm of farmers toward production, which simultaneously led to a further expansion of the agricultural production scale and increased the inputs of agricultural resources, such as pesticides, fertilizers, etc. Though it increased the economic efficiency, it also caused high agricultural carbon emissions at the same time. From the current point of view, the agricultural economic development mode currently applied in Jilin Province is still a high-carbon-based model, so it will still lead to an increase in carbon emissions in the short term. Therefore, how to reduce agricultural carbon emissions and realize the development of low-carbon agriculture and sustainable agriculture truly, while maintaining economic growth in Jilin Province, China, is still an issue to be solved.
3.3. Policy Implication
Based on the above results, to better realize the low-carbon development of agriculture in Jilin Province, this study put forward the following countermeasures and suggestions.
First, it is necessary to improve the policy of low-carbon agriculture. On the one hand, economic policies such as the low-carbon agricultural subsidy mechanism, tax relief, carbon trust fund, and financial credit support should be established to reward farmers, enterprises, and collectives who have made outstanding contributions to carbon emission reduction. On the other hand, the government should also strengthen the supervision of agricultural carbon emissions and establish and improve relevant policies and regulations, such as limiting the use of agricultural chemical fertilizers and other high-carbon agricultural means of production, establishing a carbon tax system, and so on.
Second, the industrial structure and the mode of agricultural production should be adjusted. At present, the mode of agricultural production is still in an outdated and extensive state, economic development is the driving factor for an increase in carbon emissions, and there are still many problems such as low level of technology. More measures should be taken on the basis of reasonably reducing agricultural material input and using organic fertilizers instead of chemical fertilizers, drawing lessons from the more successful low-carbon production models, such as circular agriculture, water-saving agriculture, etc., to improve the level of agricultural modernization. At the same time, optimizing the industrial structure is the main developmental strategy of Jilin Province, which vigorously promotes the developmental structure of the combination of planting and breeding. In this way, it can not only solve the problem of carbon emissions caused by livestock excrement but also reduce the input of agricultural materials. Agricultural waste resources can also be deployed. Therefore, the development of sustainable agricultural can be realized only when the extensive mode of high pollution and high emission is changed into the intensive mode of low-energy consumption and high value addition.
Third, the level of agricultural science and technology should be enhanced and new technologies should be actively introduced. New methods such as three-dimensional culture to replace traditional planting and high-light-efficiency cultivation techniques to improve rice production can be implemented so as to really keep the production benefit as the focus and consider the economic benefit as the driving force for the low-carbon supply of agriculture. There is also manure methane extraction technology to be considered, which could maximize the use of methane as renewable energy for power generation. On the one hand, it can promote the development of low-carbon agriculture; on the other hand, it can promote the development of a low-carbon economy.
Fourth, publicity and education should be further reinforced to cultivate innovative talents in agricultural science and technology. This aims to raise people’s awareness of low-carbon agriculture by organizing study tours and other activities. Through training and education of farmers’ production technology and the use of production equipment, farmers are encouraged to master more agricultural production technology, which can not only improve labor production efficiency but also reduce agricultural carbon emissions.
4. Conclusions
The following are the conclusions of the paper:
(1) From 1998 to 2018, agricultural carbon emissions in Jilin Province of China showed an upward trend as a whole, but the growth rate slowed down. From the perspective of a sequential growth rate, there is a significant range of variation, and the inter-annual variation of the sequential growth rate shows fluctuation. In recent years, the sequential growth rate has been negative. Agricultural carbon emissions in Jilin Province belong to the low-intensity, high-density category. From the perspective of animal husbandry, it is still the main cause of agricultural carbon emissions. CH4 and N2O are the two main greenhouse gases in Jilin Province at present. The proportion of CH4 is shrinking day by day. The proportion of N2O is relatively stable. In terms of the planting industry, the input of agricultural resources is still the main source of carbon emissions. The increase in carbon emissions from rice planting is mainly affected by the expansion of the planting scale and planting structure, which leads to an increase in carbon emissions from rice planting.
(2) Based on the results of LMDI decomposition, production efficiency factors, industrial structure factors, and labor factors have a strong inhibitory effect on agricultural carbon emissions in Jilin Province. Of these, production efficiency is the most important factor that restrains agricultural carbon emissions. However, economic factors have an obvious promotional effect on carbon emissions. At present, the mode of agricultural economic development in Jilin Province is still high carbon, and the transformation of the agricultural production mode is the key to achieving agricultural carbon emission reduction in Jilin Province.
Compared to existing research, this paper discusses the selection of carbon sources more comprehensively and in detail. The planting industry is not the only thing to be considered but the combination of planting and animal husbandry, covering a relatively wider and specific scope. However, there are certain limitations to this paper. It estimates the differences in agricultural carbon emissions only with regard to the aspects of total carbon emissions, structure, carbon intensity and density, and influential factors. This paper does not carefully consider the factor of straw burning, and there may be other potential factors affecting agricultural carbon emissions. The carbon emission efficiency is also a very significant reference indicator, and all these need to be considered in further follow-up studies.