References
[1]. Park Bo Rang & Chung Min Hee.(2023). Analysis of the additional energy-saving potential of residential buildings after mandatory zero-energy buildings to achieve carbon neutrality in South Korea. Building and Environment.
[2]. Ma Shimeng,He Liuyue,Fang Yu,Liu Xiuxia,Fan Yunfei & Wang Sufen.(2023). Intensive land management through policy intervention and spatiotemporal optimization can achieve carbon neutrality in advance. Journal of Cleaner Production.
[3]. Zhou Huijie,Zhu Xinman,Dai Jie & Wu Wenbin.(2023). Innovation evolution of industry-university-research cooperation under low-carbon development background: In case of 2 carbon neutrality technologies. Sustainable Energy Technologies and Assessments. doi:10.1016/J.SETA.2022.102976.
[4]. Dong Hanmin & Zhang Lin.(2023). Transition towards carbon neutrality: Forecasting Hong Kong's buildings carbon footprint by 2050 using a machine learning approach. Sustainable Production and Consumption.
[5]. Zhang Jingshu,Shen Jialin,Xu Lisong & Zhang Qi.(2023). The CO2 emission reduction path towards carbon neutrality in the Chinese steel industry: A review. Environmental Impact Assessment Review.
[6]. Jastrzębska Ilona,Ludwig Maciej,Śnieżek Edyta,Kalęba Aleksandra,Drożdż Paweł & Szczerba Jacek.(2022). Corrosion study of novel Cr-free alumina-spinel refractory material dedicated to the copper industry. Journal of the European Ceramic Society(15).
[7]. Cavanagh Mark,Ben Yosef Erez & Langgut Dafna.(2022). Fuel exploitation and environmental degradation at the Iron Age copper industry of the Timna Valley, southern Israel. Scientific Reports(1).
[8]. Zhang Hongqi,Zhao Jun,Leung Henry & Wang Wei.(2022). Multi-stage dynamic optimization method for long-term planning of the concentrate ingredient in copper industry. Information Sciences.
[9]. Akbari Kasgari, Maryam,Khademi Zare, Hassan,Fakhrzad, Mohammad Bagher,Hajiaghaei Keshteli, Mostafa & Honarvar, Mahboobeh.(2022). Designing a resilient and sustainable closed-loop supply chain network in copper industry. Clean Technologies and Environmental Policy(prepublish).
[10]. Magno Cielo D. & Guzman Ricardo Rafael S..(2021). Energy and the viability of downstream integration: Cross-country evidence from the copper industry. The Extractive Industries and Society(3).
[11]. Raposeiras Aitor C.,Movilla-Quesada Diana,Muñoz-Cáceres Osvaldo,Andrés-Valeri Valerio C. & Lagos-Varas Manuel.(2021). Production of asphalt mixes with copper industry wastes: Use of copper slag as raw material replacement. Journal of Environmental Management.
[12]. Ciszewski Mateusz,Chmielarz Andrzej,Szołomicki Zbigniew,Drzazga Michał & LeszczyńskaSejda Katarzyna.(2021). Lead Recovery from Solid Residues of Copper Industry Using Triethylenetetramine Solution. Minerals(5).
[13]. Svetlana E. Dubenko.(2021). Эффективность использования специализированного пищевого продукта у рабочих медной промышленности. Hygiene and Sanitation(3).
[14]. Correa Juan A.,Gómez Marcos,Luengo Andrés & Parro Francisco.(2021). Environmental misallocation in the copper industry. Resources Policy.
[15]. Aivaliotis P.,Anagiannis I.,Nikolakis N.,Alexopoulos K. & Makris S..(2021). Intelligent waste management system for metalwork-copper industry. Procedia CIRP.
Cite this article
Shi,P. (2023). Research on the Prediction of Copper Consumption and Recycling Changes in China under the Background of Carbon Neutrality. Advances in Economics, Management and Political Sciences,28,216-221.
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References
[1]. Park Bo Rang & Chung Min Hee.(2023). Analysis of the additional energy-saving potential of residential buildings after mandatory zero-energy buildings to achieve carbon neutrality in South Korea. Building and Environment.
[2]. Ma Shimeng,He Liuyue,Fang Yu,Liu Xiuxia,Fan Yunfei & Wang Sufen.(2023). Intensive land management through policy intervention and spatiotemporal optimization can achieve carbon neutrality in advance. Journal of Cleaner Production.
[3]. Zhou Huijie,Zhu Xinman,Dai Jie & Wu Wenbin.(2023). Innovation evolution of industry-university-research cooperation under low-carbon development background: In case of 2 carbon neutrality technologies. Sustainable Energy Technologies and Assessments. doi:10.1016/J.SETA.2022.102976.
[4]. Dong Hanmin & Zhang Lin.(2023). Transition towards carbon neutrality: Forecasting Hong Kong's buildings carbon footprint by 2050 using a machine learning approach. Sustainable Production and Consumption.
[5]. Zhang Jingshu,Shen Jialin,Xu Lisong & Zhang Qi.(2023). The CO2 emission reduction path towards carbon neutrality in the Chinese steel industry: A review. Environmental Impact Assessment Review.
[6]. Jastrzębska Ilona,Ludwig Maciej,Śnieżek Edyta,Kalęba Aleksandra,Drożdż Paweł & Szczerba Jacek.(2022). Corrosion study of novel Cr-free alumina-spinel refractory material dedicated to the copper industry. Journal of the European Ceramic Society(15).
[7]. Cavanagh Mark,Ben Yosef Erez & Langgut Dafna.(2022). Fuel exploitation and environmental degradation at the Iron Age copper industry of the Timna Valley, southern Israel. Scientific Reports(1).
[8]. Zhang Hongqi,Zhao Jun,Leung Henry & Wang Wei.(2022). Multi-stage dynamic optimization method for long-term planning of the concentrate ingredient in copper industry. Information Sciences.
[9]. Akbari Kasgari, Maryam,Khademi Zare, Hassan,Fakhrzad, Mohammad Bagher,Hajiaghaei Keshteli, Mostafa & Honarvar, Mahboobeh.(2022). Designing a resilient and sustainable closed-loop supply chain network in copper industry. Clean Technologies and Environmental Policy(prepublish).
[10]. Magno Cielo D. & Guzman Ricardo Rafael S..(2021). Energy and the viability of downstream integration: Cross-country evidence from the copper industry. The Extractive Industries and Society(3).
[11]. Raposeiras Aitor C.,Movilla-Quesada Diana,Muñoz-Cáceres Osvaldo,Andrés-Valeri Valerio C. & Lagos-Varas Manuel.(2021). Production of asphalt mixes with copper industry wastes: Use of copper slag as raw material replacement. Journal of Environmental Management.
[12]. Ciszewski Mateusz,Chmielarz Andrzej,Szołomicki Zbigniew,Drzazga Michał & LeszczyńskaSejda Katarzyna.(2021). Lead Recovery from Solid Residues of Copper Industry Using Triethylenetetramine Solution. Minerals(5).
[13]. Svetlana E. Dubenko.(2021). Эффективность использования специализированного пищевого продукта у рабочих медной промышленности. Hygiene and Sanitation(3).
[14]. Correa Juan A.,Gómez Marcos,Luengo Andrés & Parro Francisco.(2021). Environmental misallocation in the copper industry. Resources Policy.
[15]. Aivaliotis P.,Anagiannis I.,Nikolakis N.,Alexopoulos K. & Makris S..(2021). Intelligent waste management system for metalwork-copper industry. Procedia CIRP.