Next Article in Journal
Enabling Power System Restoration from Offshore Wind Power Plants in the UK
Previous Article in Journal
Dynamic Heat Transfer Modeling and Validation of Super-Long Flexible Thermosyphons for Shallow Geothermal Applications
Previous Article in Special Issue
Directions of Price Transmission on the Diesel Oil Market in Poland
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Energies
Volume 18
Issue 2
10.3390/en18020434
energies-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Artificial Intelligence in Energy Economics Research: A Bibliometric Review

by
Zhilun Jiao
1,2,
Chenrui Zhang
1 and
Wenwen Li
1,*
1
College of Economic and Social Development, Nankai University, Tianjin 300071, China
2
The Laboratory of Behavioral Economics and Policy Simulation, Nankai University, Tianjin 300071, China
*
Author to whom correspondence should be addressed.
Energies 2025, 18(2), 434; https://doi.org/10.3390/en18020434
Submission received: 7 December 2024 / Revised: 13 January 2025 / Accepted: 16 January 2025 / Published: 20 January 2025
(This article belongs to the Special Issue Energy Markets and Energy Economy)
Browse Figures
Versions Notes

Abstract

:
Artificial intelligence (AI) is gaining attention in energy economics due to its ability to process large-scale data as well as to make non-linear predictions and is providing new development opportunities and research subjects for energy economics research. The aim of this paper is to explore the trends in the application of AI in energy economics over the decade spanning 2014–2024 through a systematic literature review, bibliometrics, and network analysis. The analysis of the literature shows that the prominent research themes are energy price forecasting, AI innovations in energy systems, socio-economic impacts, energy transition, and climate change. Potential future research directions include energy supply-chain resilience and security, social acceptance and public participation, economic inequality and the technology gap, automated methods for energy policy assessment, the circular economy, and the digital economy. This innovative study contributes to a systematic understanding of AI and energy economics research from the perspective of bibliometrics and inspires researchers to think comprehensively about the research challenges and hotspots.

1. Introduction

Energy economics research is not limited to issues such as agricultural energy use and biofuels but ranges from fuel economics, fossil fuel energy issues, economic analysis of the energy sector, economic and policy issues in the power sector, and techno-economic analyses of alternative energy sources. Modeling and analytical tools used in energy economics include regional and national models to assess alternative energy futures and to evaluate the consequences of alternative energy policies [1,2].
However, as the economy and society continue to evolve, traditional management tools and production technologies are not sufficient to meet the needs of the rapidly growing economy and the concept of sustainable development. Artificial intelligence (AI) has growing potential for development and is increasingly recognized as being able to make the world a better place. In our study, concerning the definition of AI, any software technology with one of the following capabilities is considered AI: machine perception, decision-making, prediction, automated knowledge extraction from data and pattern recognition, interactive communication, and logical reasoning [3]. Since the 21st century, a large amount of valuable research has emerged on the application of AI in the field of energy economics, and scholars have been combing and analyzing the results [4]. Some scholars have begun to explore the link between AI and energy [5].
AI brings advanced equipment and tools, such as robots and drones, which can improve productivity and production efficiency. AI enables systems similar to human learning and decision-making operations, which provide optimization recommendations through machine learning algorithms to reduce energy consumption. The importance of AI for energy economics research is reflected in the fact that AI is not only an important tool for energy economics research, but it is also an important object of energy economics research, and AI plays an important role in advancing energy transition, achieving global green and low-carbon goals, promoting sustainable development, and optimizing resource allocation.
The utilization of artificial intelligence in the design of energy systems has been demonstrated to enhance both sustainability and efficiency. A notable example can be found in the work of Ardakani et al., who employed multiple optimized regression and ANN models to predict long-term electrical energy consumption in both developing and developed economies [6]. Furthermore, some scholars have applied AI to develop innovative energy systems, including a hybrid algorithm of Multi-Layer Perceptron (MLP) and Firefly Optimizer for wind energy measurement [7], using ANN algorithms and statistical analysis to develop an energy decision support system for a smart city [8], and applying Random Forests and Markov Chains to construct an integrated regional energy system [9].
The development of energy systems supported by artificial intelligence and data analytics has been applied to the energy transition of companies and countries. Dimou et al. conducted scenario simulation modeling for a green energy transition project on the Greek island of Agios Efstratios, comparing it in terms of carbon emissions and economics [10]. Yin et al. discussed the positive impact of AI software development on energy transitions in 62 economies [11]. Also, Maruejols et al. revealed the direct and indirect correlation of ethnicity on the electricity consumption of rural households based on the case of a highly ethnically diverse population in Vietnam, using the tools of machine learning and Least Absolute Shrinkage and Selection Operator (LASSO) [12]. Devaraj et al. collated online news articles and comments containing the keyword “energy transition” from Korean online news platforms, and utilized machine learning methods to study media evaluation, user sentiment, and features that influence sentiment [13].
For example, in renewable energy utilization and energy transition, AI supports large-scale data processing techniques as well as a wide variety of higher-order algorithms, where smart grids and energy management systems are used to monitor and control optimal levels of energy storage and production [14]. In recent years, machine learning, as a general-purpose AI technique, has proliferated in the research literature and has been widely used in energy economics and energy finance, such as in energy price forecasting [15,16,17], risk management [18,19,20,21], trading strategies [22,23,24], and macro energy trend analysis [25,26,27,28]. Meanwhile, bibliometric analyses conducted by some scholars have shown that support vector machines (SVMs), artificial neural networks (ANNs) and genetic algorithms (GAs) are the most commonly used techniques in energy economics papers [4].
Bibliometric methods have been applied in the field of AI and energy research for keyword clustering and the analysis of research themes and research trends. In the area of engineering and technology, Iorgovan conducted a bibliometric analysis of AI and renewable energy utilization [14]. Zhang et al. conducted a bibliometric analysis and scientific mapping of AI in the field of renewable energy utilization using VOSviewer1.6.15, CiteSpace5.8.R3, and Bibliometrix4.1.1 to investigate the application of AI in the field of renewable energy [29]. Hou et al. used bibliometrics to explore the application of big data and artificial intelligence in the energy field [30]. Olu-Ajayi et al. discussed the use of statistical and artificial intelligence tools in building energy prediction [31]. In the field of energy economics and finance, Mardani et al. provided an overview of the application of DEA modeling in the field of environmental and energy economics [32], and Wang et al. examined energy policies related to green finance [33]. Singhania et al. provided a comprehensive review of the evolution of sustainable finance research and future research directions by analyzing overall publication trends, co-authorship networks, and journal co-citations, and performing by cluster analysis [34]. Qin et al. used Bibliometrix4.3.0 to analyze the characteristics of research in the field of artificial intelligence and economic development [35]. Gao et al. reviewed the application of machine learning in business and finance, discussing the application of ML in energy marketing [36].
Overall, as shown in Figure 1, most scholars focus only on the application of AI in a certain industry, and most conduct qualitative research. Bibliometric analysis is a quantitative study based on knowledge mapping, which reflects research trends and hotspots more objectively.
These research results reflect the fact that artificial intelligence has become an important technology and research object for scholars to conduct energy economics research, but there are still limitations. From a content point of view, few scholars have analyzed the application of multiple AI technologies from a macro perspective, and most of them only focus on the application of a specific technology in a certain industry, and systematic comparative analyses are lacking. From a methodological point of view, literature studies use less quantitative research. However, quantitative research based on knowledge mapping can reflect research hotspots and trends more objectively.
In order to better understand the evolution of the application of AI in energy economics research (hereafter referred to as AI&EE) and to present a panoramic view of the field, this paper draws on bibliometric analysis to visualize and analyze research themes and trends [32,33,34,35,36,37,38,39]. The aim of this paper is to explore existing publications and comprehensively analyze the development process and research hotspots in the application of AI in energy economics. Using the bibliometric software CiteSpace as a research tool, this paper visualizes and compares the research outputs of AI technologies in energy economics between 1 January 2014 and 1 October 2024. The study is of great significance in promoting innovative international applications of AI technology in the field of energy economics and in reducing carbon emissions, and it can provide new ideas and perspectives for international research. Meanwhile, the research in this paper contributes to our systematic understanding of AI&EE.
The main contributions of this paper are as follows:
(1)
First, a descriptive statistical analysis is made. The basic characteristics of the publications are presented in terms of the number of publications per year, the evolution of the topics of the publications, and the areas of research.
(2)
To identify influential cited literature, countries, institutions and authors through network analysis.
(3)
To identify research themes from the perspective of keywords and to perform co-occurrence analysis, cluster analysis, burst detection and timeline analysis to identify future research hotspots.
(4)
To analyze future trends and challenges and limitations from current research issues.
The rest of the paper is organized as follows: Section 2 introduces the research methodology, including the bibliometric approach, data sources, search strategy and methodological framework. Subsequently, Section 3 describes the performance of the research area from four perspectives and analyzes the hot issues of current research based on keyword clustering. In addition, Section 4 provides further discussion in terms of future trends and challenges as well as limitations. Finally, Section 5 provides some conclusions.

2. Data and Methodology

The research in this paper is based on a bibliometric analysis of the application of artificial intelligence technology in energy economics.

2.1. The Definition of Energy Economics

There is no uniform concept in the academic world regarding the definition of energy economics. In this paper, energy economics is the study of economic activities, economic relations, and economic laws in the production, distribution, exchange, and consumption of energy. It involves many aspects of energy supply and demand analyses, energy price formation, energy policy formulation, energy market structure, energy efficiency, and the environmental impact of energy. In the study of energy economics, economists use a range of tools and models to perform analyses and to provide forecasts. The main research tools and models in energy economics include Computable General Equilibrium (CGE), Mathematical Programming Models, Econometric Models, Retail Net Measurement, the Energy Economics Model, Net Metering, Partial Equilibrium Models, and Techno-economic Analysis (TEA) [2].

2.2. Bibliometric Methods

In this paper, a bibliometric approach is used to visualize the analysis based on the statistics of the number of published articles and the basic background of some authors of the literature. Bibliometric methods are widely used to assess scientific results, capture scientific developments, structure scientific knowledge graphs, and identify emerging trends in specific fields [38,40,41]. CiteSpace, Ucinet, VOSviewer, and Bibliometrix are some of the most common bibliometric analysis tools used in academia.
Two powerful visualization software tools, namely VOSviewer [42] and CiteSpace [43], were used to mine and analyze the data. CiteSpace, which has been updated and optimized in several versions since its introduction in 2003, has received widespread attention in the academic community and has been used in quantitative research in several research areas. CiteSpace is a Java-based information visualization software that uses co-citation analysis theory and pathfinding network algorithms to measure the scientific literature in a particular field, explore the evolutionary paths and knowledge inflection points of a discipline, and identify and display new trends and developments in science. We used CiteSpace version 6.3 to set the parameters of threshold selection, pruning selection, time zone selection, minimum spanning tree, etc., to form the knowledge map and evaluate the network structure and clustering clarity based on the two indexes of modularity value (Q-value) and average profile value (S-value), and carried out multiple drawings by adjusting the parameter settings appropriately to achieve a more desirable result of the mapping. Thus, the research power, keywords, and timeline distribution in the fields of artificial intelligence and energy economics were systematically analyzed. VOSviewer uses the VOS mapping technique to construct distance-based two-dimensional maps, which can display maps such as authors or journals satisfactorily compared with most of the bibliometric programs used [42].

2.3. Data Collection and Filtering

The scientific nature of knowledge mapping relies on authoritative databases and requires the researcher to accurately and comprehensively retrieve the entire literature on the topic under study. To ensure the scientific validity of this study, we retrieved data from the representative and authoritative Web of Science Core Collection, which is the core journal citation index database of the Institute for Scientific Information (ISI-Institute for Scientific Information) and contains more than 18,000 authoritative and high-impact academic journals. The database consists of 10 sub-datasets (8 citation indexes and 2 chemical indexes), including SCIE, SSCI, A&HCI, ESCI, CPCI-S, CPCI-SSH, BKCI-S, BKCI-SSH, CCR-Expanded, and IC [44].
In order to search the relevant literature as comprehensively as possible, we used various terms related to AI and energy economics extracted from previous studies. In order to be able to fully cover the core research literature on the application of AI in energy economics research, the following methodology was proposed after several search attempts: TS = (“AI *” OR “Artificial intelligence *” OR “Artificial intelligent *” OR “Generative AI *” OR “Big Data *” OR “Big Models *” OR “Robotics *” OR “Multimodal model *” OR “NLP *” OR “Computer Vision *” OR “LLM *” OR “Neural networks *” OR “Unsupervised learning *” OR “Supervised learning *” OR “Feature extraction *” OR “Machine learning *” OR “Deep learning *”) AND TS = (“Energy *” OR “Crude Oil *” OR “Natural Gas *” OR “Gasoline *” OR “Carbon *” OR “Electricity *” OR “Solar *” OR “Wind *” OR “Renewable *” OR “Climate Policy *” OR “Energy Efficiency *” OR “Environmental Policy *” OR “Environmental Regulation *”).
In WoS, all publications can be categorized into different types. The distribution of the document types is shown in Table 1. In order to improve the accuracy and scientific validity of the data, the document types were further manually selected as Articles (726; 81.39%), removing Proceedings papers (141; 15.81%), Early Access papers (54; 6.05%), Review Articles (24; 2.69%), Book Chapters (2; 0.22%), Corrections (2; 0.22%), and Editorial Material (2; 0.22%).
Each publication included in the Web of Science Core Collection belongs to at least one subject category. Each record corresponds to at least one Web of Science category field, which contains the subject category to which its source publication belongs. To limit the literature search to the field of economics, publications with the subject categories Economics, Management, Business, and Business Finance were filtered. The search was again precise, and 494 documents were manually screened.
The period examined was from 1 January 2014 to 1 October 2024. The time interval chosen for the bibliometric analysis is the most recent decade, which is a representative period during which both the fields of AI and energy economics have experienced significant changes and challenges. This paper aims to explore the research trends and hotspots in the field of AI&EE during the last decade. The final data obtained included complete document record information such as the title, author, journal, abstract, keywords, references, and source journal.

2.4. The Research Framework of the Methodology

The aim of this paper is to provide a comprehensive bibliometric analysis of energy economics research and artificial intelligence. First, relevant literature was searched for in the appropriate databases according to the search strategy [45]. Next, the performance was analyzed in terms of annual publication trends, disciplinary distribution, and research areas. Then, citations, regions, institutions, and authors were studied through CiteSpace bibliometric methods and tools. Meanwhile, hotspots, future trends, and challenges in these research areas were identified. The research framework of the methodology of this paper is shown in Figure 2.

3. Bibliometric Analysis

The results of the bibliometric analysis of the application of artificial intelligence in energy economics can be obtained based on the search strategy and analysis tools. This can be demonstrated by the following three aspects: descriptive statistical analysis, network analysis, and keyword analysis.

3.1. Descriptive Statistical Analysis

3.1.1. The Annual Trends in Publications

The number of publications is an important indicator to measure the development trend of a particular field in a specific period. At the same time, we can also see more intuitively the change in the research hotness of the field, which is of great significance in analyzing the development trend in a particular field and to predict its future trend. Figure 3 shows the annual publications on artificial intelligence in energy economics research.
From a general point of view, the number of papers published in the field of AI&EE research has shown an increasing trend over the years. Specifically, AI&EE research can be roughly divided into two developmental stages. The first stage is from 2014 to 2017; the number of papers published in this time period is generally small and the speed of publication is slow, with a total of 40 AI&EE-related papers published, and the average number of papers is 10, indicating that the importance of AI technology had not yet been taken into account in the field of energy economics during this period. The 21st United Nations Climate Change Conference passed the Paris Agreement in 2015, and therefore the number of papers published in 2016 increased significantly, with a growth rate of 300%.
The second phase, from 2018 to 2024, shows that international research on AI&EE experienced a spurt of growth, with an average growth rate of 45.81%. In particular, 2024 was the year with the highest number of publications as well as the fastest growth, with a total of 145 publications in 2024 as of October 2024, representing a growth rate of 79%.
The analyses found that the timing in this area is related to international energy policy, international energy relations, and international energy markets. In particular, 2017 is known as the year of AI application, when many big events in the field of artificial intelligence emerged, such as AlphaGo’s victory over Ke Jie, the human world’s top-ranked chess player. Japan, Canada, Singapore, and China had begun the process of signing national AI strategies, giving strong financial support to AI. By the end of 2018, more than 20 countries had formed their own national AI strategies. In September 2021, The World Economic Forum (WEF) released the report Accelerating the Energy Transition with Artificial Intelligence, which provides insights into the potential of AI applications in energy transition. In 2022, the global energy market underwent drastic changes, which were reflected in the international demand for crude oil exceeding expectations and the energy crisis in Europe due to the Russia–Ukraine conflict. In the same year, OpenAI released ChatGPT, a generative AI. These factors led to a strong focus on AI&EE in academia, with an 87% increase in publications in 2024 compared with 2022.
Based on current trends, the number of publications will continue to grow in 2024. In conclusion, AI&EE has received increasing attention from academia in recent years, and the foreseeable future will be a golden period for research in this field.

3.1.2. Evolution of Research Themes

Figure 4 illustrates the evolution of research themes in the publications of the top ten countries, highlighting a clear homogenizing trend of strong continued focus on machine learning and AI across countries. Between 2014 and 2015, research efforts in pioneering countries such as China, the United States, the United Kingdom, Australia, and India focused on energy efficiency and energy forecasting, which relied on third-party forecasting and employed time-series analysis. This reflects a shift in research methodology toward learning algorithms and an increasing reliance on the data themselves rather than the variables of interest for forecasting.
Between 2015 and 2016, machine learning and artificial neural networks were the main research themes in France, Germany, Turkey, Italy, and the Netherlands. This marks a significant shift in the research landscape, with a clear preference for advanced research techniques and tools in energy-related research.
Beyond 2020, research themes in all countries in the graph are centered primarily around machine learning and artificial intelligence, reflecting a global convergence in the use of these technologies in energy research, with machine learning and artificial intelligence becoming a cornerstone of energy economics research.
Energy economists are increasingly recognizing the revolutionary potential of machine learning and AI in energy economics research. AI technologies provide powerful tools for data analysis, forecasting, and optimization, and the analysis of the evolution of the themes shows that the field of AI&EE research is maturing.

3.1.3. Top 10 Research Areas of Publications

Each publication covers at least one research area. The top 10 research areas are shown in Figure 5. The most popular research areas are Economics (318) and Management (156), with 64% and 32%, respectively. These are followed by Business (109), Environmental Studies (74), and Regional & Urban Planning (46). The remaining five research areas are Business, Finance (43), Energy & Fuels (43), Environmental Sciences (40), Operations Research & Management Science (35), and Social Sciences and Mathematical Methods (20). An analysis of the distribution of disciplines shows that AI is widely used in the field of energy economics, especially in economic analysis, management decision-making, and business operations. At the same time, there are fewer studies related to the integration of AI with information systems in energy economics research, as well as insufficient research on applications in agricultural energy economics and policy making. Artificial intelligence in energy economy research is mainly concentrated in the fields of economics, management, business, and environmental studies, while less research is specialized in computer science, agricultural economics and policy, international relations, and law.
An overview of the distribution of journals for AI&EE-related research reveals the disciplinary configuration of the field as well as the profile and preferences of core journals. To illustrate the distribution of journals, Table 2 lists the top ten high-impact journals in terms of the percentage of published articles. The 494 papers in the field are distributed across 129 journals. These journals are authoritative in the field of economics and management and are located in Q1 or Q2 of the WoS database. They are critical knowledge aggregation and dissemination platforms in the field of AI&EE. In terms of the number of journals published, the first ranked journal is Energy Economics (98; 19.87%), a top journal in the field of energy economics and energy finance, with topics ranging from energy conversion and use to energy commodities and derivatives markets, followed by Technological Forecasting and Social Change, Energy Policy, and International Journal of Forecasting in the field of energy economics.

3.2. Network Analysis

This section analyses publications from four perspectives: citations, regions, institutions, and authors. First, the knowledge base of the AI&EE field is analyzed through the literature co-citation network. In addition, it is analyzed from the following perspectives: collaboration between countries, collaboration between institutions, and collaboration between authors.

3.2.1. Citation Analysis

Highly cited literature is called basic knowledge in bibliometrics, which is the classic literature in the field and can reflect the overall knowledge base of the field. Therefore, the knowledge base and knowledge structure of the research field is analyzed through the clustering of highly cited literature and co-cited literature. Literature co-citation is when two publications are simultaneously cited in another publication. The classic literature in a given field is often cited repeatedly, not only as an essential research result in the field but also as constituting the knowledge base of the field. The co-citation analysis of the literature in the field of AI&EE helps to tap the knowledge base of AI&EE research.
Table 3 lists the titles of the top 10 cited publications and their related information. The table is arranged in ascending order of citations. The co-citation analysis of the literature shows that a total of three articles possess the highest citation rate in the study of AI in energy economics. Among them, the most cited and earliest published document is the publication titled “Does energy diversification cause an economic slowdown? Evidence from a newly constructed energy”. Gozgor et al. analyzed the differences in the impact of energy diversification on economic growth by constructing a new energy diversification index using the nonlinear panel autoregressive distributed lag (NPARDL) method, and found that energy diversification has a positive effect on growth in major economies in the long run, but in the short run, it has a positive effect on growth for some countries and a negative impact in all low-income economies [46]. Lau et al. published in 2023 the article titled “Introducing a new measure of energy transition: Green quality of energy mix and its impact on CO2 emissions”, which has a high citation frequency and has co-citation relationships with several articles [47]. The article adopts a new measure of energy transition, the green quality of energy mix (GREENQ), and uses systematic GMM, FGLS, and PCSE panel data techniques to examine the impact of per capita income, institutional quality, and technology in 36 OECD countries on the emissions of CO2 from 1970–2021.
Sinha et al. proposed a new energy transition indicator, an output-side indicator based on the energy ladder assumption, and analyzed the impact of social imbalances and governance quality on the drivers of energy transition using a two-step system GMM approach [48]. Chishti et al. used econometric methods such as quantile vector autoregression, cross-sectional quantile plots, wavelet quantile correlation, and nonparametric Granger causality tests, and found that green financing, green technology, and environmental policies have a positive effect on energy transition, while geopolitical risks have a negative effect [49].
Shahbaz et al. discussed the interplay between financial development and energy diversification in Australia, factoring in natural capital, structural change, economic growth, and export diversification, and revealed that financial development positively affects energy diversification, with an inverted “U”-shaped nonlinear relationship [50]. The classical literature focuses on four main research themes: energy transition, energy diversification, energy market forecasting and trading, and the development of new technologies and tools for traditional industries (e.g., industrial robotics).
The co-citation network of journals can be seen in Figure 6, which consists of five clusters corresponding to the four colors in the figure, and the top three cited journals are Energy Economics (1819 citations), Energy Policy (863 citations), and Journal of Cleaner Production (803 citations). All three journals are JCRQ1 (i.e., outstanding) journals.
The purple cluster relates to renewable energy and its integration into energy systems, highlighting the importance of sustainable energy solutions. The yellow cluster focuses on the application of energy in various fields, including smart grids, energy management systems, and photovoltaic power generation, emphasizing the practical utility of energy use, with strong links to the field of engineering. The red cluster covers the fields of economics, finance, and management, with special emphasis on energy economics, energy policy, and energy finance. The blue cluster is dedicated to energy policy, reflecting the role of governance and regulatory frameworks in guiding the energy sector toward sustainable development and efficiency. Finally, the green cluster represents the cross-cutting areas of manufacturing, production systems management, and the development of green production materials, demonstrating efforts to improve the sustainability of industrial processes. As illustrated in Figure 6, each node symbolizes a journal, and a link between two nodes indicates that both journals appear in the same publication. The size of the node reflects the frequency of the appearance. This means that the larger the node, the more frequently the journal appeared. In contrast, the width of the links indicates the number of times the two journals appear together. In particular, in Figure 6, the nodes clustered in red are not only the largest but also have the most links, revealing a strong correlation between different research topics. This suggests that energy economics research is deeply cross-studied and rich in academic interactions with other subject areas, such as energy policy, energy applications, and renewable energy. The green engineering technology cluster is relatively independent, which implies a certain degree of research isolation in the field. Cross-research between the energy economics research and engineering technology clusters has not yet reached the desired depth, indicating that more interdisciplinary collaboration may be needed in order to promote knowledge integration and innovation.

3.2.2. Cooperation Network of Nations

The number of publications directly reflects a country’s academic impact on a particular research topic. Therefore, the types of nodes in CiteSpace are selected based on the concept of “country”.
The collaborative network of countries is shown in Figure 7. Sixty-five countries participated in this study out of the 494 retrieved documents. A node represents a country, and a link between two nodes indicates that the two countries have collaborative publications. The figure has 65 nodes and 88 links in the network (with a density of 0.0423), indicating a closer collaborative network between countries. The darker the green color, the larger the node and the higher the number of publications in the corresponding country. The more extensive the links between the nodes, the closer the cooperation between the two countries.
As shown in Table 4, China is the most productive country in this field, with 196 publications, while the United States is second, with 83 publications. England and France closely follow them, with 62 and 40 publications, respectively. In general, publications are concentrated in Asia, Europe, and North America, with an apparent geographic clustering for AI&EE. It is worth mentioning that China and the United States have the highest number of publications, with both having an early focus in the field of AI&EE but with very low centrality (0). This indicates that scholars in both countries mainly collaborate with scholars within their own countries, and there are not many cross-country collaborative achievements with other countries, so the collaborative network is rather limited.
Furthermore, in Figure 7, the larger the circle of nodes, the higher the centrality. Nodes with purple outer circles have higher centrality. Australia, India, and Saudi Arabia are the top three countries with the highest centrality. This indicates that these countries have a lot of interactions and collaborations with other countries. Table 4 shows the top 10 countries with the highest number of publications and their related information. More than half of the countries in Table 4 have a centrality of more than 0.10. This means that they can be considered critical nodes with a significant impact.
Among them, Australia has the highest centrality (0.61) with 37 publications, accounting for 35.71% of the total, which indicates that Australia has already had extensive interaction and cooperation with other countries.

3.2.3. Institutional Cooperation Network

A collaborative network analysis of the literature’s issuing institutions yields Figure 8. The institutions with the highest number of articles in AI&EE are the Chinese Academy of Sciences and the Beijing Institute of Technology, with 17 and 11 articles, respectively. Other institutions with eight or more articles are the University of Chinese Academy of Sciences, Lebanese American University, Anhui University of Finance & Economics, and the University of International Business & Economics.
In terms of cooperation, there are 245 nodes and 203 links in the network (a density of 0.0068), indicating that there is some relationship between the issuing institutions.
A collaborative network relationship with the Chinese Academy of Sciences as the core, containing research institutions such as the University of Chinese Academy of Sciences, Academy of Mathematics & System Sciences, and South China University of Technology, is shown in Figure 8. These are focusing on issues in the forecasting of crude oil prices, forecasting the environmental performance of power companies, and stock market returns of energy companies.
Overall, there is a high intensity of cooperation and closer links between research institutions. A wide and close network of academic cooperation has been formed, with essentially all publications that have been published having been achieved through cross-institutional cooperation. However, international cooperation is not as strong, since there is a lack of transnational cooperation.
The CiteSpace calculation was applied to derive the global core institutions for research in AI&EE, as shown in Table 5. We have identified two issues that are worth paying attention to:
First, the analysis of the disciplinary attributes of the institutes shows that they are dominated by scientific and technological research institutes, supplemented by general research institutes. From an interdisciplinary perspective, the research on AI and energy economic is related to the dominant disciplines of research institutes, such as economics, environmental science, mathematics, and computing.
Second, the regional distribution needs to be balanced, and research institutions are mainly concentrated in Asia, Africa, Europe, and North America, all of which are significantly developed or developing countries with large populations. They are also mainly concentrated in the northern hemisphere, with fewer core research institutions in the southern hemisphere, suggesting that there are significant geographical differences in core research institutions.

3.2.4. Co-Authorship Network

Due to the large number of research scholars in the field of AI&EE, this study only analyzes the information of core authors here. Core authors, as the main force promoting academic progress and scientific development in a specific field, have high paper production rates and academic influence, leading the development of a specific discipline. By analyzing the knowledge graph of published authors, the core authors in the intersection of AI and energy economics can be presented.
As shown in Figure 9, the scholar with the most publications in the field of AI in energy economics is Wang, Shouyang (8) with a total of 533 citations, forming a collaborative group with Li, Xuerong; Wei, Yunjie; Li, Yuze; and Jiang, Shangrong. They mainly focus on research themes about the prediction of crude oil prices and financial market sentiment research. High-frequency authors also include Wang, Yudong (6) and Song, Malin (6). These authors form the core authors and core research team in AI&EE and have a strong influence on the research areas of AI&EE.
According to the formula of Price’s (Price) law, i.e., M = 0.749 × (Nmax)1/2, Nmax refers to the number of publications of the most prolific authors. It is derived that the threshold of prolific authors in the sample is 2.1185. According to the principle of rounding, M = 2, so the authors whose publications are more remarkable than (or equal to) 2 are considered prolific authors in this study. Statistically, it is found that the total number of articles published by high-yield authors in the sample is 67, accounting for 14%, indicating the formation of a group of core authors and research teams with high output and high impact.

3.3. Keyword Analysis

Keyword analysis helps to identify topics in a particular field. This section performs co-occurrence analysis, keyword clustering analysis, burst detection analysis of keywords, and timeline visualization to identify research hotspots, frontiers, and trends. This process uses two visualization tools, VOSviewer and CiteSpace.

3.3.1. Co-Occurrence Analysis

Co-occurrence analysis of keywords helps in understanding the research hotspots in a particular field. The nodes represent the keywords, while the node’s size indicates the frequency of keyword occurrence, and the connecting line indicates the number of keyword co-occurrences, which represents the intensity of co-occurrence.
As shown in Figure 10, the top 10 keywords with the highest frequency of occurrence are “machine learning”, “impact”, “artificial intelligence”, “model”, “ big data”, “consumption”, “neural networks”, “performance”, “regression”, and “management”, which indicate that the hot topics in the field are mainly related to these keywords. It indicates that international research in the field of AI&EE is mainly focused on reducing greenhouse gas emissions, energy modeling, and predicting future trends with the help of machine learning, neural networks, and various optimization algorithms. Mediated centrality indicates the mediating role of keywords in the graph, and keywords with high mediated centrality are the core themes of the field. In the CiteSpace tool, nodes with a mediator centrality greater than 0.1 are called vital nodes. As can be seen from Table 6, “demand”, “consumption”, “decomposition”, and “future” series terms have become the critical nodes for research in the field of AI&EE.

3.3.2. Keyword Clustering

Based on the analysis of the co-occurrence and mutation of keywords in AI&EE, this paper uses the keyword clustering atlas to sort out the hotspots of the research and the degree of concentration of the research in order to further understand whether the hotspots of the research in AI&EE are familiar or not. The keywords are clustered according to the log-likelihood rate, with a total of 20 clusters, and the results are shown in Figure 11.
The clustering module value of Q = 0.7927 means that the clustering structure is significant, and the average profile value of S = 0. 0.8878, which is greater than 0.7, means that the clustering is convincing. The clusters are classified and organized according to the principle of homogeneity, which is shown in Table 7. We divide the above 20 clusters into four main research themes: artificial intelligence and the energy market, sustainable development and environmental policy, energy consumption and demand management, and socio-economic impacts.
Moreover, based on the principle of homogeneity, the four organized clustering results can be divided into the following five major research themes:
  • Artificial Intelligence Forecasting for Energy Markets—Energy price forecasting
One of the most important forecasts in energy market price forecasting is that of crude oil prices, and oil price movements and shocks can have a significant impact on financial markets and the real economy [58]. Oil price is an important reference factor for the government’s macro forecasting and policy decision-making, as well as an important reference standard for investors’ asset allocation. Zhang et al. selected a large number of predictors based on the LASSO method (LASSO) and the elastic net method (elastic net) to predict the return of oil prices [53].
Predicting energy price tools can be subdivided into three categories: The first category includes traditional methods such as autoregressive integrated moving average models and generalized autoregressive conditional heteroskedasticity. The second category is artificial intelligence methods, such as artificial neural networks, deep learning [59], and LSTM [60]. The third category is the heterogeneous autoregressive (HAR) model.
Yang et al. constructed a novel kernel-based generalized stochastic-interval multilayer perceptron (KG-iMLP) method based on the D(K) distance of the kernel function for predicting high-volatility interval-valued returns of crude oil. In the empirical analysis of the weekly and daily returns of WTI crude oil, the proposed method is demonstrated to have excellent forecasting performance, which is able to provide stable and accurate forecasts for both point and interval values [61].
The current focus of crude oil price forecasting has shifted from deterministic to uncertainty indicators due to the emergence of various uncertainty indices associated with financial and energy markets. Tissaoui et al. use a new machine learning tool approach, XGBoost modeling, applied to the SVM and ARIMAX (p,d,q) models to examine the impact of natural gas prices and other uncertainty indicators on the ability to predict oil prices [62].
2.
Artificial Intelligence Innovation for Energy Systems in Businesses and Industries
Artificial intelligence (AI) has great potential to improve energy system efficiency and to reduce energy system costs. Currently, enterprises are applying AI to optimize enterprise workflows, streamline enterprise operational procedures, and serve enterprise customers as well as to assist in operational decision-making. While AI has the potential to save energy in the process of enterprise digital transformation, it is inherently characterized by high energy consumption. The Zhang et al. study listed Chinese manufacturing enterprises, finding that the widespread application of AI can significantly reduce the energy intensity of enterprises, with one additional unit of industrial robots per 100 workers reducing the energy intensity (EI) of the enterprise by about 2.5%, a reduction that is more pronounced in high-energy-consuming, non-labor-intensive, and state-owned enterprises [63]. Wang et al. discussed the relationship between AI adoption rates and corporate green innovation efficiency in Chinese energy firms from the perspectives of CEOs and boards of directors, concluding that energy firms with higher AI adoption rates have stronger positive impacts on green innovation [64].
Industrial robotics is a key technology for Industry 4.0 and the artificial intelligence revolution. The International Federation of Robotics (IFR) defines an industrial robot as an automatically controlled, reprogrammable, programmable multipurpose manipulator for industrial automation applications [65]. The application of industrial robots can promote technological progress in manufacturing, significantly improve industrial productivity and energy efficiency, reduce carbon intensity, and realize energy savings and emission reductions. Bennedsen et al. investigated the carbon-reducing effect of the application of industrial robots, combining fixed effects with nonparametric neural network regression, and found the existence of an Environmental Kuznets Curve (EKC) in production emissions [66].
3.
Socio-economic impacts
Artificial intelligence has infrastructural spillover properties, and employment and labor markets are important research themes in the AI&EE field. In the short term, AI can replace some low-skilled employees, thus reducing the market demand for labor, creating a substitution effect in the labor force, and reducing the share of labor income. In the long run, AI can expand the demand for highly skilled employees and increase the share of labor income. Thus, AI technology can reshape the job market by replacing workers and creating jobs [54].
Niet et al. examined the socio-economic impacts of AI integration in the EU electricity market and showed that AI improves the sustainability, reliability, and affordability of the market. However, AI increases the complexity of the electricity market and its dependence on digital infrastructure, which may pose potential risks in terms of cybersecurity, privacy, and technological autonomy. Due to the high cost of running and improving AI programs, AI is not widely used in the EU electricity market, despite the fact that AI can reduce the burden of grassroots staff on complex electricity market tasks [67].
4.
Energy transition in economic sectors
Energy transition is an important research theme in the current energy field. With economic and social development, the large-scale development and utilization of fossil energy has brought about problems such as resource depletion, climate change, and geopolitical conflicts. Energy transition refers to the replacement of the main source of energy from fossil energy to non-fossil energy and the formation of green production methods and lifestyles. The current application of artificial intelligence has been widely used in the fossil energy sector but is characterized by complexity and high cost, which is a contributing factor in energy transition [68]. Zhao et al. investigated whether artificial intelligence can facilitate the transition of economies from traditional fossil energy to renewable energy (RE), and the results of the study showed that in the short and medium term, AI has a negative impact on the increase in the share of renewable energy, while in the long term, AI increases the share of renewable energy in the total amount of energy and accelerates the transition to RE [69]. Zhao et al. also discuss the asymmetry of the impact of AI on renewable energy development across economies, while finding that its post-financing can play an effective moderating role [70].
5.
Climate change and carbon emissions
The rapid development, upgrading, and wide-scale application of AI will inevitably have an impact on climate change, and several scholars have discussed the interplay between the application of AI and climate change and energy use.
Zhou et al. explored the impact of adopting industrial robots on pollution emissions and energy efficiency in various provinces and regions in China [71]. Zhong et al. investigated the dual role of AI applications on the environment and climate change and studied the synergistic effect of AI in reducing pollutants and carbon emissions using the system generalized method of moments (SYS-GMM) [72].
In discussing the impact of advances brought about by information and science and technology on carbon emissions, some studies have suggested that AI has a dampening effect on carbon emissions; however, because the application of AI requires a high level of technology and advanced computing hardware, it may have a negative impact on carbon emissions and energy use. Therefore, Zhong et al. attempted to discuss whether the impact of AI on carbon emission reduction is positive or negative and used quantile regression and the PSTR model to study the impact of AI on carbon emission in 66 countries, finding that the carbon emission reduction effect of AI only exists in high-carbon emission and high-income countries [73].

3.3.3. Burst Detection Analysis of Keywords

The burst detection feature analyses keywords that produce significant changes in a short period and can show the start and end time of the keyword. Table 8 lists the top 20 keywords with the strongest citation bursts.
The keyword “neural networks” in 2014 with showed the highest burst strength (5.14), indicating that AI plays an increasingly important role in energy economic and is gradually becoming a research frontier. Notably, the keyword “investment” has an intensity value of 2.98, which appears prominently in 2022, and is expected to continue to receive academic attention beyond 2024, which is related to the increasing global focus on sustainable energy investments.

3.3.4. Timeline Visualization

Analyzing the evolutionary path of a research area enables researchers to have a clearer picture of the development of the research topic and the direction of development, and the research trend of the topic can also be predicted based on the evolutionary path. We can understand the evolution of the research topic by analyzing the temporal naming and frequency of keywords. In this section, a timeline analysis of keywords from 2014 to 2024 is conducted with CiteSpace. The time slice is set to 1, and the timeline review of the keywords is shown in Figure 12. The Timeline function of CiteSpace enables such visual analysis of the evolution path, and at the same time, relevant keywords can also be clustered into themes—in this case, into 17 keyword cluster labels.
The concept of “#0 artificial intelligence” is a crucial research direction. The results of the timeline graph reflect a clear trend of homogenization, where there is strong continuity of national attention to machine learning and AI. We categorized the evolution of research themes into three phases:
The first phase is from 2014 to 2015. This was the initial phase of AI&EE research, with work focused on energy efficiency and energy forecasting. These studies relied on third-party forecasting and used time-series analysis. The keywords “regression” and “big data analytics” both appeared for the first time in 2014.
The second phase is from 2015 to 2016. Machine learning and artificial neural networks became major research themes. This marked a major shift in AI&EE. Energy economists tended to adopt more advanced research techniques and tools during this period. The keywords “time series”, “consumption”, and “algorithm” all appeared for the first time in 2016.
The third phase is from 2020 to the present. Research in this phase is more specialized, and the models are more complex. Research themes are centered around machine learning and artificial intelligence, reflecting a global convergence in the use of these technologies in energy research, which has become a cornerstone of energy economics research.
Artificial intelligence technologies provide powerful tools for energy data analysis, forecasting, and optimization, and the analysis of keyword timeline graphs suggests that the field of artificial intelligence and energy economics research is maturing.

4. Further Discussion

To better understand the evolution of AI&EE research themes, we can categorize the results of above-mentioned analysis into the following six future trends and two challenges.

4.1. Future Trends

4.1.1. Energy Supply-Chain Resilience and Security

As international political changes, the issue of energy supply-chain security is becoming a future research trend in the field of AI&EE. Resources supply-chain security is mainly related to the international situation and geopolitics. Given the long-term energy interdependence between the EU and the Russian Federation, Ilie et al. discussed the long-term energy security of the EU 27 and the dependency of the EU on imports of gas, oil, and petroleum products from the Russian Federation [74]. Deng et al. analyzed the impacts of the outbreak of the Russia–Ukraine war on the risk-related systems of oil, food, and renewable energy through a time-varying QVAR model and constructed a risk early-warning system for oil–food–renewable energy by using an ATT-CNN-LSTM model, which found that the outbreak of the Russia–Ukraine war promoted the development of renewable energy and enhanced the food-renewable energy correlation [75]. Zhong, Yufei et al. discussed how developing the use of artificial intelligence in energy market uncertainty could disrupt global supply chains [76].
In energy supply-chain resilience, AI can perform risk management tasks, identifying and assessing potential risks in the energy supply chain, such as natural disasters and market volatility. In the logistics and distribution part of the energy supply chain, self-driving vehicles, drones, and robots can conduct automated inspections to monitor and maintain the critical infrastructure of the energy network. In quantifying supply-chain resilience, AI can simulate different market and operational scenarios to assess the performance and resilience of the supply chain in the face of various shocks.

4.1.2. Social Acceptance and Public Participation

Social awareness and acceptance of AI technologies in the energy sector is a key factor in the mass commercialization of AI. New technologies in the energy sector also need to be aligned with the preferences of mass society and require public acceptance and participation for their widespread deployment and operation. Conversely, public acceptance of and participation in AI can also positively feed back into the diffusion and application of AI technologies in the energy sector. In order to assess public acceptance of fusion, Cabelkova et al. used big-data techniques as a criterion for social acceptance through participant interviews, internet news, newspapers and magazines, and the rate of support for the technology was assessed [77]. Enhancements that can be made include popularizing AI in teaching and publicizing it through mass media in order to increase public awareness of AI applications in the energy sector.

4.1.3. Economic Inequality and the Technology Gap

The acquisition and application of AI technology has a high threshold, requiring a high level of technological development and long-term sustained infrastructure investment, which naturally precludes low-income countries and less profitable firms from entering the AI space. In terms of the impact path, the aggregation of AI in these high-income countries and strong profitability firms in realizing the cumulative benefits of resources will lead to the gradual accumulation of additional benefits from AI in these individuals, such as customer service capabilities, productivity, and energy intensity. Ultimately, this will lead to unequal economic development, and this inequality, at the firm level, manifests itself in the nature of firms, such as monopolies and non-monopolies and state-owned and non-state-owned firms. At the national level, it is manifested in the imbalance of economic development between countries and regions, and from 2017, major economies began to develop AI as their main national development strategy, and AI competition will become more and more intense. Few articles have studied the inter-individual economic development gap brought about by AI development from the field of energy. Sinha et al. developed a policy framework for realizing the energy transition by considering social imbalance and regulatory effectiveness, with social imbalance dampening the positive impacts of energy-transition drivers [48].
The high threshold of AI will bring about a gradual increase in both the technology gap and the knowledge gap. The technology gap will lead to an unequal distribution of benefits in the energy economy. Rikap et al. discuss the knowledge monopoly of the State Grid Corporation of China (SGCC), a leader in AI applications in the energy sector, using big-data techniques [78]. SGCC relies on public research institutions and public funding as well as on innovation and energy policies to grow from being a global knowledge monopoly.

4.1.4. Automated Methods for Energy Policy Assessment

In the energy policy field, traditional assessment methods often rely on expert experience and qualitative analysis, which limit the objectivity and accuracy of policy assessment to some extent. The automated approach to energy policy assessment is mainly reflected in the ability of AI to simulate different policy scenarios and to assess the potential impact of these policies on the energy market and the socio-economic sector. Through machine learning algorithms, AI can process and analyze large amounts of historical and real-time data and identify the relationship between policy changes and energy market responses, thus predicting the possible consequences of policy changes. This automated approach not only improves the efficiency of policy assessment but also enhances the accuracy and reliability of the results. Neto-Bradley et al. used a tree-ensemble-based machine learning predictive analytics approach to identify targets for clean-cooking policy interventions [79]. This suggests that automated methods can be used not only as a tool for in-depth analysis but also to provide policymakers with more specific guidance for action.

4.1.5. Circular Economy (CE)

The circular economy is a model for economic growth, the core of which is emissions reduction and reuse and resource mobilization, and it is characterized by low consumption, low emissions, and high productivity. Vigorous efforts have been made to develop a circular economy and significantly increase the utilization and recycling rates of key materials such as steel, cement, fertilizers, and plastics. Anwar et al. explore how two technologies, artificial intelligence (AI) and digital twins (DT), are contributing to consumption transformation and sustainable development for a circular economy in agriculture [80].

4.1.6. Digital Economy

The digital economy can affect economic development significantly. Meanwhile, the impact of the digital economy on the environment and resources is an important research topic for future studies. Wang et al. found that AI will have a significant positive impact on the strategy of the high-quality development of energy (HED) in the areas with a developed digital economy [81]. Lai et al. used China’s National Big Data Comprehensive Pilot Zone (NBD-CPZ) as a quasi-natural experiment and found that the impact of the digital economy on urban eco-efficiency was more significant in resource-based and high-energy-intensity cities [82].

4.2. Challenges

4.2.1. Government and Administrative Support

According to Duan et al., with regard to AI, legal issues have become a significant challenge [83]. The role of the government is crucial, especially in terms of how the government develops adequate policies, regulations, and legal frameworks to guide and prevent misuse of the technology.

4.2.2. Policy, Law, and Intellectual Property Protection

One of the main problems with AI research in energy economics is the lack of accessible data, which hampers research conducted for the public good; hence, there is a need for an AI data-sharing platform. Therefore, legislative and regulatory measures are needed to facilitate data sharing and digital transformation among individuals, universities, businesses, and governments. Another issue is the ethical issues raised by AI and the lack of sound legal provisions for AI in the law; hence, the recommendation for ethical audits of high-risk AI systems that should be used for environmental issues. From a legal perspective, Mylrea et al. explored the privacy laws, torts, and precedents relevant to smart-energy technology opportunities and examined the challenges involved [84].

5. Conclusions

This paper presents a bibliometric analysis of relevant publications in AI&EE from different perspectives, revealing their essential characteristics, knowledge structures, hotspots, and trends. First, a performance analysis was conducted to present the essential characteristics of the publications, including the annual indicators, thematic evolution, and research areas. Then, to identify collaborations in the research area, analyses were conducted from four perspectives: citations, countries, institutions, and authors. Next, co-occurrence analysis, keyword clustering analysis, burst detection analysis of keywords, and timeline visualization were performed to identify research hotspots, frontiers, and trends. Finally, further discussions were conducted.

5.1. Key Findings

Based on the results of the bibliometric analysis, the key findings are summarized as follows:
(1)
Descriptive statistical analysis reveals that the number of publications in AI&EE has been increasing year by year. There is strong continued interest in machine learning and artificial intelligence across countries. The most popular research areas are economics (318) and management (156). The top-ranked journal is Energy Economics, followed by Technology Forecasting and Social Change, Energy Policy, and International Journal of Forecasting in the field of energy economics.
(2)
In network analysis, the most influential and most cited articles are those by Gozgor et al., Lau et al., and Sinha et al. China is the country with the most achievements, with Australia and India and other countries collaborating most closely. Chinese Academy of Sciences and Beijing Institute of Technology are the most influential institutions. The scholar with the most publications in the field of AI&EE is Shouyang, Wang (8), with a total of 533 citations.
(3)
The keyword analysis demonstrates that the hotspots of AI&EE research are concentrated on “ machine learning”, “ impact”, “ artificial intelligence”, “model”, and so on. The keyword “investment”, with a strength of 2.98, emerged in 2022, and it is expected that academic attention will continue beyond 2024. The current prominent research themes are energy price forecasting, artificial intelligence innovations in energy systems, socio-economic impacts, energy transition, and climate change. Based on the timeline analysis, the resulting 17 clusters can be considered as the core directions of current AI&EE research.
(4)
Potential future research directions include energy supply-chain resilience and security, social acceptance and public participation, economic inequality and the technology gap, automated methods for energy policy assessment, the circular economy, and the digital economy. Future challenges include governmental and administrative support as well as legal and intellectual property protection. The results of the survey provide some suggestions for future research.

5.2. Limitations

This paper provides a comprehensive analysis of publications related to AI&EE from 2014 to 2024. It can help scholars interested in AI&EE research to better understand the field’s evolution and to reflect on it from multiple perspectives. At the same time, this paper has some limitations. A single database source and the use of specific search settings may have resulted in some publications being missed. This paper focuses on presenting a panoramic view of the field rather than analyzing the details in depth. Therefore, the discussion in this paper has some limitations.
In the future, we should work on researching and developing new AI-based techniques. We will consider using additional databases, more loosely defined terms for data collection, and alternative bibliometric analysis methods. In addition, more advanced methods for comprehensive analyses, such as machine learning and text mining, will be further employed. In the future, we will continue to focus on developing AI&EE research.

Author Contributions

Z.J.: Conceptualization, Formal analysis, Writing—review and editing, Supervision. C.Z.: Data curation, Methodology, Software, Formal analysis, Writing—original draft, Writing—review and editing. W.L.: Validation, Data curation, Writing—review and editing. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Social Science Fund of China, grant number 23BJY127.

Conflicts of Interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Abbreviations

AIArtificial intelligence
EEEnergy economics
PSTRPanel smooth transition model
RERenewable energy
LSTMLong short-term memory
WTIWest Texas intermediate
EUThe European Union
QVARQuantile vector autoregression

References

  1. Smyth, R.; Narayan, P.K. Applied Econometrics and Implications for Energy Economics Research. Energy Econ. 2015, 50, 351–358. [Google Scholar] [CrossRef]
  2. Tyner, W.E.; Herath, N. Energy Economics. Appl. Eco. Perspect. Pol. 2018, 40, 174–186. [Google Scholar] [CrossRef]
  3. Vinuesa, R.; Azizpour, H.; Leite, I.; Balaam, M.; Dignum, V.; Domisch, S.; Felländer, A.; Langhans, S.D.; Tegmark, M.; Fuso Nerini, F. The Role of Artificial Intelligence in Achieving the Sustainable Development Goals. Nat. Commun. 2020, 11, 233. [Google Scholar] [CrossRef] [PubMed]
  4. Ghoddusi, H.; Creamer, G.G.; Rafizadeh, N. Machine Learning in Energy Economics and Finance: A Review. Energy Econ. 2019, 81, 709–727. [Google Scholar] [CrossRef]
  5. Wang, H.; Lei, Z.; Zhang, X.; Zhou, B.; Peng, J. A Review of Deep Learning for Renewable Energy Forecasting. Energy Convers. Manag. 2019, 198, 111799. [Google Scholar] [CrossRef]
  6. Ardakani, F.J.; Ardehali, M.M. Long-Term Electrical Energy Consumption Forecasting for Developing and Developed Economies Based on Different Optimized Models and Historical Data Types. Energy 2014, 65, 452–461. [Google Scholar] [CrossRef]
  7. Deo, R.C.; Ghorbani, M.A.; Samadianfard, S.; Maraseni, T.; Bilgili, M.; Biazar, M. Multi-Layer Perceptron Hybrid Model Integrated with the Firefly Optimizer Algorithm for Windspeed Prediction of Target Site Using a Limited Set of Neighboring Reference Station Data. Renew. Energy 2018, 116, 309–323. [Google Scholar] [CrossRef]
  8. Ghadami, N.; Gheibi, M.; Kian, Z.; Faramarz, M.G.; Naghedi, R.; Eftekhari, M.; Fathollahi-Fard, A.M.; Dulebenets, M.A.; Tian, G. Implementation of Solar Energy in Smart Cities Using an Integration of Artificial Neural Network, Photovoltaic System and Classical Delphi Methods. Sustain. Cities Soc. 2021, 74, 103149. [Google Scholar] [CrossRef]
  9. Lei, Y.; Wang, D.; Jia, H.; Li, J.; Chen, J.; Li, J.; Yang, Z. Multi-Stage Stochastic Planning of Regional Integrated Energy System Based on Scenario Tree Path Optimization under Long-Term Multiple Uncertainties. Appl. Energy 2021, 300, 117224. [Google Scholar] [CrossRef]
  10. Dimou, A.; Vakalis, S. Technoeconomic Analysis of Green Energy Transitions in Isolated Grids: The Case of Ai Stratis—Green Island. Renew. Energy 2022, 195, 66–75. [Google Scholar] [CrossRef]
  11. Yin, H.-T.; Wen, J.; Chang, C.-P. Going Green with Artificial Intelligence: The Path of Technological Change towards the Renewable Energy Transition. Oeconomia Copernic. 2023, 14, 1059–1095. [Google Scholar] [CrossRef]
  12. Maruejols, L.; Höschle, L.; Yu, X. Vietnam between Economic Growth and Ethnic Divergence: A LASSO Examination of Income-Mediated Energy Consumption. Energy Econ. 2022, 114, 106222. [Google Scholar] [CrossRef]
  13. Devaraj, J.; Madurai Elavarasan, R.; Shafiullah, G.; Jamal, T.; Khan, I. A Holistic Review on Energy Forecasting Using Big Data and Deep Learning Models. Int. J. Energy Res. 2021, 45, 13489–13530. [Google Scholar] [CrossRef]
  14. Iorgovan, D. Artificial Intelligence and Renewable Energy Utilization. Proc. Int. Conf. Bus. Excell. 2024, 18, 2776–2783. [Google Scholar] [CrossRef]
  15. Mostafa, M.M.; El-Masry, A.A. Oil Price Forecasting Using Gene Expression Programming and Artificial Neural Networks. Econ. Model. 2016, 54, 40–53. [Google Scholar] [CrossRef]
  16. Mercadal, I. Dynamic Competition and Arbitrage in Electricity Markets: The Role of Financial Players. Am. Econ. J.-Microecon. 2022, 14, 665–699. [Google Scholar] [CrossRef]
  17. Guo, L.; Huang, X.; Li, Y.; Li, H. Forecasting Crude Oil Futures Price Using Machine Learning Methods: Evidence from China. Energy Econ. 2023, 127, 107089. [Google Scholar] [CrossRef]
  18. Mangla, S.K.; Srivastava, P.R.; Eachempati, P.; Tiwari, A.K. Exploring the Impact of Key Performance Factors on Energy Markets: From Energy Risk Management Perspectives. Energy Econ. 2024, 131, 107373. [Google Scholar] [CrossRef]
  19. Thakur, J.; Hesamzadeh, M.R.; Date, P.; Bunn, D. Pricing and Hedging Wind Power Prediction Risk with Binary Option Contracts. Energy Econ. 2023, 126, 106960. [Google Scholar] [CrossRef]
  20. Fang, G.; Deng, Y.; Ma, H.; Zhang, J.; Pan, L. Energy Financial Risk Management in China Using Complex Network Analysis. J. Organ. End. User Comput. 2023, 35, 29. [Google Scholar] [CrossRef]
  21. Duesterhoeft, M.; Schiemann, F.; Walther, T. Let’s Talk about Risk! Stock Market Effects of Risk Disclosure for European Energy Utilities. Energy Econ. 2023, 125, 106794. [Google Scholar] [CrossRef]
  22. Gong, X.; Li, M.; Guan, K.; Sun, C. Climate Change Attention and Carbon Futures Return Prediction. J. Futures Mark. 2023, 43, 1261–1288. [Google Scholar] [CrossRef]
  23. Janczura, J.; Wojcik, E. Dynamic Short-Term Risk Management Strategies for the Choice of Electricity Market Based on Probabilistic Forecasts of Profit and Risk Measures. The German and the Polish Market Case Study. Energy Econ. 2022, 110, 106015. [Google Scholar] [CrossRef]
  24. Li, S.-T.; Chiu, K.-C.; Wu, C.-C. Apply Big Data Analytics for Forecasting the Prices of Precious Metals Futures to Construct a Hedging Strategy for Industrial Material Procurement. Manag. Decis. Econ. 2023, 44, 942–959. [Google Scholar] [CrossRef]
  25. Zhang, L.; Padhan, H.; Singh, S.K.; Gupta, M. The Impact of Renewable Energy on Inflation in G7 Economies: Evidence from Artificial Neural Networks and Machine Learning Methods. Energy Econ. 2024, 136, 107718. [Google Scholar] [CrossRef]
  26. Neghab, D.P.; Cevik, M.; Wahab, M.I.M.; Basar, A. Explaining Exchange Rate Forecasts with Macroeconomic Fundamentals Using Interpretive Machine Learning. Comput. Econ. 2024. [Google Scholar] [CrossRef]
  27. Kocaarslan, B.; Mushtaq, R. The Impact of Liquidity Conditions on the Time-Varying Link between US Municipal Green Bonds and Major Risky Markets during the COVID-19 Crisis: A Machine Learning Approach. Energy Policy 2024, 184, 113911. [Google Scholar] [CrossRef]
  28. Kocaarslan, B. US Dollar and Oil Market Uncertainty: New Evidence from Explainable Machine Learning. Financ. Res. Lett. 2024, 64, 105375. [Google Scholar] [CrossRef]
  29. Zhang, L.; Ling, J.; Lin, M. Artificial Intelligence in Renewable Energy: A Comprehensive Bibliometric Analysis. Energy Rep. 2022, 8, 14072–14088. [Google Scholar] [CrossRef]
  30. Hou, Y.; Wang, Q. Big Data and Artificial Intelligence Application in Energy Field: A Bibliometric Analysis. Env. Sci. Pollut. Res. 2022, 30, 13960–13973. [Google Scholar] [CrossRef]
  31. Olu-Ajayi, R.; Alaka, H.; Sunmola, F.; Ajayi, S.; Mporas, I. Statistical and Artificial Intelligence-Based Tools for Building Energy Prediction: A Systematic Literature Review. IEEE Trans. Eng. Manag. 2024, 71, 14733–14753. [Google Scholar] [CrossRef]
  32. Mardani, A.; Streimikiene, D.; Balezentis, T.; Saman, M.Z.M.; Nor, K.M.; Khoshnava, S.M. Data Envelopment Analysis in Energy and Environmental Economics: An Overview of the State-of-the-Art and Recent Development Trends. Energies 2018, 11, 2002. [Google Scholar] [CrossRef]
  33. Wang, M.; Li, X.; Wang, S. Discovering Research Trends and Opportunities of Green Finance and Energy Policy: A Data-Driven Scientometric Analysis. Energy Policy 2021, 154, 112295. [Google Scholar] [CrossRef]
  34. Singhania, M.; Chadha, G.; Prasad, R. Sustainable Finance Research: Review and Agenda. Int. J. Financ. Econ. 2024, 29, 4010–4045. [Google Scholar] [CrossRef]
  35. Qin, Y.; Xu, Z.; Wang, X.; Skare, M. Artificial Intelligence and Economic Development: An Evolutionary Investigation and Systematic Review. J. Knowl. Econ. 2024, 15, 1666–1702. [Google Scholar] [CrossRef]
  36. Gao, H.; Kou, G.; Liang, H.; Zhang, H.; Chao, X.; Li, C.-C.; Dong, Y. Machine Learning in Business and Finance: A Literature Review and Research Opportunities. Financ. Innov. 2024, 10, 86. [Google Scholar] [CrossRef]
  37. Agrawal, R.; Majumdar, A.; Kumar, A.; Luthra, S. Integration of Artificial Intelligence in Sustainable Manufacturing: Current Status and Future Opportunities. Oper. Manag. Res. 2023, 16, 1720–1741. [Google Scholar] [CrossRef]
  38. Chen, C.; Dubin, R.; Kim, M.C. Emerging Trends and New Developments in Regenerative Medicine: A Scientometric Update (2000–2014). Expert. Opin. Biol. Ther. 2014, 14, 1295–1317. [Google Scholar] [CrossRef]
  39. Kumar, A.; Bhattacharya, T.; Shaikh, W.A.; Roy, A.; Chakraborty, S.; Vithanage, M.; Biswas, J.K. Multifaceted Applications of Biochar in Environmental Management: A Bibliometric Profile. Biochar 2023, 5, 11. [Google Scholar] [CrossRef]
  40. Chen, C.; Hu, Z.; Liu, S.; Tseng, H. Emerging Trends in Regenerative Medicine: A Scientometric Analysis in CiteSpace. Expert. Opin. Biol. Ther. 2012, 12, 593–608. [Google Scholar] [CrossRef]
  41. Synnestvedt, M.B.; Chen, C.; Holmes, J.H. CiteSpace II: Visualization and Knowledge Discovery in Bibliographic Databases. AMIA Annu. Symp. Proc. 2005, 2005, 724–728. [Google Scholar] [PubMed]
  42. Van Eck, N.J.; Waltman, L. Software Survey: VOSviewer, a Computer Program for Bibliometric Mapping. Scientometrics 2010, 84, 523–538. [Google Scholar] [CrossRef] [PubMed]
  43. Chen, C. CiteSpace II: Detecting and Visualizing Emerging Trends and Transient Patterns in Scientific Literature. J. Am. Soc. Inf. Sci. 2006, 57, 359–377. [Google Scholar] [CrossRef]
  44. Liu, W. The Data Source of This Study Is Web of Science Core Collection? Not Enough. Scientometrics 2019, 121, 1815–1824. [Google Scholar] [CrossRef]
  45. Tranfield, D.; Denyer, D.; Smart, P. Towards a Methodology for Developing Evidence-Informed Management Knowledge by Means of Systematic Review. Br. J. Manag. 2003, 14, 207–222. [Google Scholar] [CrossRef]
  46. Gozgor, G.; Paramati, S.R. Does Energy Diversification Cause an Economic Slowdown? Evidence from a Newly Constructed Energy Diversification Index. Energy Econ. 2022, 109, 105970. [Google Scholar] [CrossRef]
  47. Lau, C.K.; Gozgor, G.; Mahalik, M.K.; Patel, G.; Li, J. Introducing a New Measure of Energy Transition: Green Quality of Energy Mix and Its Impact on CO2 Emissions. Energy Econ. 2023, 122, 106702. [Google Scholar] [CrossRef]
  48. Sinha, A.; Bekiros, S.; Hussain, N.; Nguyen, D.K.; Khan, S.A. How Social Imbalance and Governance Quality Shape Policy Directives for Energy Transition in the OECD Countries? Energy Econ. 2023, 120, 106642. [Google Scholar] [CrossRef]
  49. Chishti, M.Z.; Sinha, A.; Zaman, U.; Shahzad, U. Exploring the Dynamic Connectedness among Energy Transition and Its Drivers: Understanding the Moderating Role of Global Geopolitical Risk. Energy Econ. 2023, 119, 106570. [Google Scholar] [CrossRef]
  50. Shahbaz, M.; Siddiqui, A.; Ahmad, S.; Jiao, Z. Financial Development as a New Determinant of Energy Diversification: The Role of Natural Capital and Structural Changes in Australia. Energy Econ. 2023, 126, 106926. [Google Scholar] [CrossRef]
  51. Ahmad, T.; Zhang, D.; Huang, C.; Zhang, H.; Dai, N.; Song, Y.; Chen, H. Artificial Intelligence in Sustainable Energy Industry: Status Quo, Challenges and Opportunities. J. Clean. Prod. 2021, 289, 125834. [Google Scholar] [CrossRef]
  52. Wang, E.-Z.; Lee, C.-C.; Li, Y. Assessing the Impact of Industrial Robots on Manufacturing Energy Intensity in 38 Countries. Energy Econ. 2022, 105, 105748. [Google Scholar] [CrossRef]
  53. Zhang, Y.; Ma, F.; Wang, Y. Forecasting Crude Oil Prices with a Large Set of Predictors: Can LASSO Select Powerful Predictors? J. Empir. Financ. 2019, 54, 97–117. [Google Scholar] [CrossRef]
  54. Acemoglu, D.; Restrepo, P. Robots and Jobs: Evidence from US Labor Markets. J. Political Econ. 2020, 128, 2188–2244. [Google Scholar] [CrossRef]
  55. Lee, C.-C.; Qin, S.; Li, Y. Does Industrial Robot Application Promote Green Technology Innovation in the Manufacturing Industry? Technol. Forecast. Soc. Change 2022, 183, 121893. [Google Scholar] [CrossRef]
  56. Caldara, D.; Iacoviello, M. Measuring Geopolitical Risk. Am. Econ. Rev. 2022, 112, 1194–1225. [Google Scholar] [CrossRef]
  57. Li, Y.; Jiang, S.; Li, X.; Wang, S. The Role of News Sentiment in Oil Futures Returns and Volatility Forecasting: Data-Decomposition Based Deep Learning Approach. Energy Econ. 2021, 95, 105140. [Google Scholar] [CrossRef]
  58. Kilian, L.; Vigfusson, R.J. The Role of Oil Price Shocks in Causing U.S. Recessions. J. Money Credit. Bank. 2017, 49, 1747–1776. [Google Scholar] [CrossRef]
  59. Yang, K.; Hu, N.; Tian, F. Forecasting Crude Oil Volatility Using the Deep Learning-Based Hybrid Models With Common Factors. J. Futures Mark. 2024, 44, 1429–1446. [Google Scholar] [CrossRef]
  60. Jiang, P.; Nie, Y.; Wang, J.; Huang, X. Multivariable Short-Term Electricity Price Forecasting Using Artificial Intelligence and Multi-Input Multi-Output Scheme. Energy Econ. 2023, 117, 106471. [Google Scholar] [CrossRef]
  61. Yang, K.; Xu, X.; Wei, Y.; Wang, S. Forecasting Interval-Valued Returns of Crude Oil: A Novel Kernel-Based Approach. J. Forecast. 2024, 43, 2937–2953. [Google Scholar] [CrossRef]
  62. Tissaoui, K.; Zaghdoudi, T.; Hakimi, A.; Nsaibi, M. Do Gas Price and Uncertainty Indices Forecast Crude Oil Prices? Fresh Evidence Through XGBoost Modeling. Comput. Econ. 2023, 62, 663–687. [Google Scholar] [CrossRef] [PubMed]
  63. Zhang, W.; Zeng, M. Is Artificial Intelligence a Curse or a Blessing for Enterprise Energy Intensity? Evidence from China. Energy Econ. 2024, 134, 107561. [Google Scholar] [CrossRef]
  64. Wang, Z.; Zhang, T.; Ren, X.; Shi, Y. AI Adoption Rate and Corporate Green Innovation Efficiency: Evidence from Chinese Energy Companies. Energy Econ. 2024, 132, 107499. [Google Scholar] [CrossRef]
  65. Graetz, G.; Michaels, G. Robots at Work. Rev. Econ. Stat. 2018, 100, 753–768. [Google Scholar] [CrossRef]
  66. Bennedsen, M.; Hillebrand, E.; Jensen, S. A Neural Network Approach to the Environmental Kuznets Curve. Energy Econ. 2023, 126, 106985. [Google Scholar] [CrossRef]
  67. Niet, I.; Van den Berghe, L.; van Est, R. Societal Impacts of AI Integration in the EU Electricity Market: The Dutch Case. Technol. Forecast. Soc. Change 2023, 192, 122554. [Google Scholar] [CrossRef]
  68. Zhang, X.; Khan, K.; Shao, X.; Oprean-Stan, C.; Zhang, Q. The Rising Role of Artificial Intelligence in Renewable Energy Development in China. Energy Econ. 2024, 132, 107489. [Google Scholar] [CrossRef]
  69. Zhao, Q.; Wang, L.; Stan, S.-E.; Mirza, N. Can Artificial Intelligence Help Accelerate the Transition to Renewable Energy? Energy Econ. 2024, 134, 107584. [Google Scholar] [CrossRef]
  70. Zhao, C.; Dong, K.; Wang, K.; Nepal, R. How Does Artificial Intelligence Promote Renewable Energy Development? The Role of Climate Finance. Energy Econ. 2024, 133, 107493. [Google Scholar] [CrossRef]
  71. Zhou, W.; Zhuang, Y.; Chen, Y. How Does Artificial Intelligence Affect Pollutant Emissions by Improving Energy Efficiency and Developing Green Technology. Energy Econ. 2024, 131, 107355. [Google Scholar] [CrossRef]
  72. Zhong, W.; Liu, Y.; Dong, K.; Ni, G. Assessing the Synergistic Effects of Artificial Intelligence on Pollutant and Carbon Emission Mitigation in China. Energy Econ. 2024, 138, 107829. [Google Scholar] [CrossRef]
  73. Zhong, J.; Zhong, Y.; Han, M.; Yang, T.; Zhang, Q. The Impact of AI on Carbon Emissions: Evidence from 66 Countries. Appl. Econ. 2024, 56, 2975–2989. [Google Scholar] [CrossRef]
  74. Ilie, A.G.; Zlatea, M.L.E.; Negreanu, C.; Dumitriu, D.; Pentescu, A. Reliance on Russian Federation Energy Imports and Renewable Energy in the European Union. Amfiteatru Econ. 2023, 25, 780. [Google Scholar] [CrossRef]
  75. Deng, Y.; Fang, G.; Zhang, J.; Ma, H. Dynamic Connectedness Among Oil, Food Commodity, and Renewable Energy Markets: Novel Perspective from Quantile Dependence and Deep Learning. J. Knowl. Econ. 2023, 15, 9935–9974. [Google Scholar] [CrossRef]
  76. Zhong, Y.; Chen, X.; Wang, Z.; Lin, R.F.-Y. The Nexus among Artificial Intelligence, Supply Chain and Energy Sustainability: A Time-Varying Analysis. Energy Econ. 2024, 132, 107479. [Google Scholar] [CrossRef]
  77. Cabelkova, I.; Strielkowski, W.; Streimikiene, D.; Cavallaro, F.; Streimikis, J. The Social Acceptance of Nuclear Fusion for Decision Making towards Carbon Free Circular Economy: Evidence from Czech Republic. Technol. Forecast. Soc. Change 2021, 163, 120477. [Google Scholar] [CrossRef]
  78. Rikap, C. Becoming an Intellectual Monopoly by Relying on the National Innovation System: The State Grid Corporation of China’s Experience. Res. Policy 2022, 51, 104472. [Google Scholar] [CrossRef]
  79. Neto-Bradley, A.P.; Choudhary, R.; Bazaz, A. Slipping through the Net: Can Data Science Approaches Help Target Clean Cooking Policy Interventions? Energy Policy 2020, 144, 111650. [Google Scholar] [CrossRef]
  80. Anwar, A.Z.; Zain, M.; Hasan, R.; Al Salman, H.; Alkhamees, B.F.; Almisned, F.A. Circular Economy Advances with Artificial Intelligence and Digital Twin: Multiple-Case Study of Chinese Industries in Agriculture. J. Knowl. Econ. 2024. [Google Scholar] [CrossRef]
  81. Wang, B.; Wang, J.; Dong, K.; Nepal, R. How Does Artificial Intelligence Affect High-Quality Energy Development? Achieving a Clean Energy Transition Society. Energy Policy 2024, 186, 114010. [Google Scholar] [CrossRef]
  82. Lai, A.; Li, Z.; Hu, X.; Wang, Q. Does Digital Economy Improve City-Level Eco-Efficiency in China? Econ. Anal. Policy 2024, 81, 1198–1213. [Google Scholar] [CrossRef]
  83. Duan, Y.; Edwards, J.S.; Dwivedi, Y.K. Artificial Intelligence for Decision Making in the Era of Big Data—Evolution, Challenges and Research Agenda. Int. J. Inf. Manag. 2019, 48, 63–71. [Google Scholar] [CrossRef]
  84. Mylrea, M. Smart Energy-Internet-of-Things Opportunities Require Smart Treatment of Legal, Privacy and Cybersecurity Challenges. J. World Energy Law. Bus. 2017, 10, 147–158. [Google Scholar] [CrossRef]
Energies 18 00434 g001
Figure 1. The novelty of the study.
Figure 1. The novelty of the study.
Energies 18 00434 g001
Energies 18 00434 g002
Figure 2. The research framework of the methodology used in this paper. Note: * is a wildcard, commonly used in computer programming languages to represent “any text”.
Figure 2. The research framework of the methodology used in this paper. Note: * is a wildcard, commonly used in computer programming languages to represent “any text”.
Energies 18 00434 g002
Energies 18 00434 g003
Figure 3. Trends in the number of annual publications.
Figure 3. Trends in the number of annual publications.
Energies 18 00434 g003
Energies 18 00434 g004
Figure 4. Evolution of research themes in the top 10 national publications.
Figure 4. Evolution of research themes in the top 10 national publications.
Energies 18 00434 g004
Energies 18 00434 g005
Figure 5. Number of publications in different research areas.
Figure 5. Number of publications in different research areas.
Energies 18 00434 g005
Energies 18 00434 g006
Figure 6. Co-citation of cited journals.
Figure 6. Co-citation of cited journals.
Energies 18 00434 g006
Energies 18 00434 g007
Figure 7. National cooperation network.
Figure 7. National cooperation network.
Energies 18 00434 g007
Energies 18 00434 g008
Figure 8. Collaborative networks of research institutions.
Figure 8. Collaborative networks of research institutions.
Energies 18 00434 g008
Energies 18 00434 g009
Figure 9. The collaboration network of authors.
Figure 9. The collaboration network of authors.
Energies 18 00434 g009
Energies 18 00434 g010
Figure 10. Visualization of the keyword co-occurrence network.
Figure 10. Visualization of the keyword co-occurrence network.
Energies 18 00434 g010
Energies 18 00434 g011
Figure 11. Keyword clustering graph.
Figure 11. Keyword clustering graph.
Energies 18 00434 g011
Energies 18 00434 g012
Figure 12. Timeline chart.
Figure 12. Timeline chart.
Energies 18 00434 g012
Table 1. Distribution of document types.
Table 1. Distribution of document types.
Document TypeNumberPercentage
Articles72681.39%
Proceedings papers14115.81%
Early Access papers546.05%
Review Articles242.69%
Book Chapters20.22%
Corrections20.22%
Editorial Material20.22%
Book Reviews10.11%
Table 2. Distribution of key journals.
Table 2. Distribution of key journals.
NumberJournalTPPercentageIF
1Energy Economics9819.84%13.6
2Technological Forecasting and Social Change448.91%12.9
3Energy Policy367.29%9.3
4International Journal of Forecasting295.87%6.9
5Journal of Forecasting142.83%3.4
6Business Strategy and the Environment122.43%12.5
7European Journal of Operational Research112.23%6.0
8Computational Economics112.23%1.9
9International Review of Financial Analysis91.82%7.5
10Finance Research Letters81.62%7.4
Note: TP = number of publications; IF = 2024 journal impact factor.
Table 3. The top 10 cited publications.
Table 3. The top 10 cited publications.
FreqLabelSourceTitle
20Gozgor G (2022) [46]Energy EconomicsDoes energy diversification cause an economic slowdown? Evidence from a newly constructed energy diversification index
20Lau CK (2023) [47]Energy EconomicsIntroducing a new measure of energy transition: Green quality of energy mix and its impact on CO2 emissions
20Sinha A (2023) [48]Energy EconomicsHow social imbalance and governance quality shape policy directives for energy transition in the OECD countries?
19Chishti MZ (2023) [49]Energy EconomicsExploring the dynamic connectedness among energy transition and its drivers: Understanding the moderating role of global geopolitical risk
19Shahbaz M (2023) [50]Energy EconomicsFinancial development as a new determinant of energy diversification: The role of natural capital and structural changes in Australia
18Ahmad T (2021) [51]Journal of Cleaner ProductionArtificial intelligence in sustainable energy industry: Status quo, challenges and opportunities
16Ghoddusi H (2019) [4]Energy EconomicsMachine learning in energy economics and finance: A review
12Wang EZ (2022) [52]Energy EconomicsAssessing the impact of industrial robots on manufacturing energy intensity in 38 countries
12Zhang YJ (2019) [53]Journal of Empirical FinanceForecasting crude oil prices with a large set of predictors: Can LASSO select powerful predictors?
10Acemoglu D (2020) [54]Journal of Political EconomyRobots and jobs: Evidence from US labor markets
10Lee CC (2022) [55]Technological Forecasting and Social ChangeDoes industrial robot application promote green technology innovation in the manufacturing industry?
10Caldara D (2022) [56]American Economic ReviewMeasuring geopolitical risk
10Li YZ (2021) [57]Energy EconomicsThe role of news sentiment in oil futures returns and volatility forecasting: Data-decomposition-based deep learning approach
Table 4. The top 10 countries with the highest number of publications.
Table 4. The top 10 countries with the highest number of publications.
No.FrequencyProportion CentralityNationYear
119640%0PEOPLES R CHINA2014
28317%0USA2015
36213%0.29ENGLAND2014
4408%0.07FRANCE2016
5388%0.04GERMANY2016
6377%0.61AUSTRALIA2014
7326%0.57INDIA2015
8224%0ITALY2017
9184%0.06SPAIN2018
10173%0.18NETHERLANDS2016
Table 5. Core institutions.
Table 5. Core institutions.
NumberLabelFreqProportion
1Chinese Academy of Sciences173.44%
2Beijing Institute of Technology112.23%
3University of Chinese Academy of Sciences102.02%
4Lebanese American University81.62%
5Anhui University of Finance & Economics81.62%
6University of International Business & Economics81.62%
7Academy of Mathematics & System Sciences71.42%
8University of London61.21%
9Central South University61.21%
10Indian Institute of Management (IIM System)61.21%
Total8717.61%
Table 6. Top 10 keywords in terms of centrality.
Table 6. Top 10 keywords in terms of centrality.
NumberFreqCentralityKeywordYear
1220.35demand2015
2340.3consumption2015
3110.28decomposition2014
4150.2future2018
5310.2regression2014
6130.19big-data analytics2015
7120.19artificial neural network2018
8340.15neural networks2014
9180.15efficiency2017
10170.14algorithm2016
Table 7. Four main research topics.
Table 7. Four main research topics.
FocusIDClusterSizeSilhouetteYearTypical Keywords and Their Centrality
Artificial Intelligence and the Energy Market#0artificial intelligence350.8412019artificial intelligence (26.41; 1.0 × 10−4); energy transition (15.57; 1.0 × 10−4); renewable energy (11.1; 0.001); Bayesian networks (8.74; 0.005); portfolio diversification (8.74; 0.005)
#1volatility forecasting 310.9012019volatility forecasting (13.9; 0.001); crude oil market (9.93; 0.005); artificial neural networks (9.22; 0.005); time-series forecasting (7.23; 0.01); artificial intelligence (6.6; 0.05)
#4tail risk250.8152017tail risk (6.08; 0.05); Bayesian extreme learning machine (6.08; 0.05); oil–food–renewable energy market (6.08; 0.05); crude oil shocks (6.08; 0.05); precious metal forecasting (6.08; 0.05)
#5big-data analytics250.9362017big-data analytics (12.4; 0.001); energy efficiency (9.55; 0.005); carbon emission efficiency (8.56; 0.005); heterogeneity (6.62; 0.05); electricity demand (5.28; 0.05)
#6smart grid250.8112018smart grid (11.42, 0.001); electricity market (11.42; 0.001); privacy (11.42; 0.001); risk management (7.72; 0.01); quantile regression (7.72; 0.01)
#9neural networks200.9552016neural networks (12.8; 0.001); energy intensity (11.11; 0.001); crude oil (8.75; 0.005); correlation (5.54; 0.05); choice models (5.54; 0.05)
Artificial Intelligence and the Energy Market#10big data200.912018big data (12.86; 0.001); smart cities (8.17; 0.005); imperfect quality components (5.93; 0.05); bidirectional fixed-effect model (5.93; 0.05); smart energy communities (5.93; 0.05)
#11digital twin200.9412015digital twin (12.14; 0.001); market research (8.42; 0.005); patents (8.42; 0.005); multivariate forecasting (6.06; 0.05); decomposition (6.06; 0.05)
#12deep learning200.92020deep learning (14.65; 0.001); energy price forecasting (11.04; 0.001); carbon tax (11.04; 0.001); regression analysis (7.35; 0.01); parameter instability (7.35; 0.01)
#13data mining160.9562017data mining (8.3; 0.005); artificial intelligence (AI) (8.3; 0.005); technological implications (7.86; 0.01); information technology (IT) (7.86; 0.01); correlation analysis (7.86; 0.01)
#16riskmetrics712015riskmetrics (10.83; 0.001); leveraging (10.83; 0.001); genetic programming algorithm (10.83; 0.001); higher-order neural network (10.83; 0.001); multilayer perceptron neural network (10.83; 0.001)
#19Gaussian processes102014Gaussian processes (13.29; 0.001); gradient-boosting machines (10.52; 0.005); load forecasting (10.52; 0.005); machine learning (0.23; 1.0); artificial intelligence (0.15; 1.0)
Sustainable Development and Environmental Policy#2sustainable development290.7282020sustainable development (17.2; 1.0 × 10−4); Industry 4.0 (12.03; 0.001); carbon emissions (5.64; 0.05); information technology (5.45; 0.05)
#3corporate governance290.9312021corporate governance (9.43; 0.005); o13 (5.81; 0.05); big-data economy (4.71; 0.05); tfp (4.71; 0.05); wind (4.71; 0.05)
#7carbon emission240.962017carbon emission (12.7; 0.001); CO2 emissions (12.53; 0.001); green investment technology (6.33; 0.05); adaptive management (6.33; 0.05); thresholds (6.33; 0.05)
#8green innovation230.9012023green innovation (14.31; 0.001); digital transformation (14.26; 0.001); digital finance (12.45; 0.001); environmental regulation (12.45; 0.001); green technology innovation (9.51; 0.005)
Energy Consumption and Demand Management#14machine learning140.9522016machine learning (39.53; 1.0 × 10−4); energy poverty prediction (10.49; 0.005); eco-innovation (5.24; 0.05); iot (5.24; 0.05); atfp (5.24; 0.05)
#15electricity demand110.8282021electricity demand (8.86; 0.005); energy consumption structure (8.15; 0.005); copula function model (8.15; 0.005); multi-factor dynamic support vector machine model (8.15; 0.005); advanced index (8.15; 0.005)
Socio-economic Impacts#17theory of planned behavior412017theory of planned behavior (11.7; 0.001); compliance behavior (11.7; 0.001); IT relatedness (11.7; 0.001); compliance knowledge (11.7; 0.001); compliance support system (11.7; 0.001)
#18operational improvement312016operational improvement (12.11; 0.001); customer demand anticipation (12.11; 0.001); customer attendance (12.11; 0.001); attendance strategies (12.11; 0.001); relationship (12.11; 0.001)
Table 8. Top 20 keywords with the strongest citation bursts.
Table 8. Top 20 keywords with the strongest citation bursts.
Keywords Year Strength Begin End 2014–2024
demand 2015 3.62 2015 2019 ▃▃▃▃▃▂▂▂▂▂
neural networks 2014 5.14 2016 2019 ▂▂▃▃▃▃▂▂▂▂▂
artificial neural networks 2016 4.13 2016 2020 ▂▂▃▃▃▃▃▂▂▂▂
time series 2016 3.43 2016 2020 ▂▂▃▃▃▃▃▂▂▂▂
regression 2014 2.68 2016 2018 ▂▂▃▃▃▂▂▂▂▂▂
algorithm 2016 2.56 2016 2021 ▂▂▃▃▃▃▃▃▂▂▂
consumption 2015 2.04 2017 2018 ▂▂▃▃▂▂▂▂▂▂
big data 2014 3.77 2018 2020 ▂▂▂▂▃▃▃▂▂▂▂
neural network 2018 2.75 2018 2021 ▂▂▂▂▃▃▃▃▂▂▂
electricity demand 2018 2.3 2018 2020 ▂▂▂▂▃▃▃▂▂▂▂
artificial neural network 2018 2.05 2018 2021 ▂▂▂▂▃▃▃▃▂▂▂
prices 2018 2.05 2018 2019 ▂▂▂▂▃▃▂▂▂▂▂
system 2018 2.03 2018 2020 ▂▂▂▂▃▃▃▂▂▂▂
prediction 2019 3.33 2019 2021 ▂▂▂▂▂▃▃▃▂▂▂
power 2019 2.2 2019 2021 ▂▂▂▂▂▃▃▃▂▂▂
dynamics 2020 3.59 2020 2021 ▂▂▂▂▂▂▃▃▂▂▂
big data analytics 2015 2.29 2020 2022 ▂▂▂▂▂▃▃▃▂▂
inference 2020 2.05 2020 2021 ▂▂▂▂▂▂▃▃▂▂▂
ICT 2021 2.07 2021 2022 ▂▂▂▂▂▂▂▃▃▂▂
investment 2022 2.98 2022 2024 ▂▂▂▂▂▂▂▂▃▃▃
Note: Red represents strong citation bursts. Blue and light blue mean no strongest citation bursts in the period.
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Jiao, Z.; Zhang, C.; Li, W. Artificial Intelligence in Energy Economics Research: A Bibliometric Review. Energies 2025, 18, 434. https://doi.org/10.3390/en18020434

AMA Style

Jiao Z, Zhang C, Li W. Artificial Intelligence in Energy Economics Research: A Bibliometric Review. Energies. 2025; 18(2):434. https://doi.org/10.3390/en18020434

Chicago/Turabian Style

Jiao, Zhilun, Chenrui Zhang, and Wenwen Li. 2025. "Artificial Intelligence in Energy Economics Research: A Bibliometric Review" Energies 18, no. 2: 434. https://doi.org/10.3390/en18020434

APA Style

Jiao, Z., Zhang, C., & Li, W. (2025). Artificial Intelligence in Energy Economics Research: A Bibliometric Review. Energies, 18(2), 434. https://doi.org/10.3390/en18020434

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop