A Comprehensive Material Flow Account for Lao PDR to Inform Environmental and Sustainability Policy

Modern environmental and sustainability policy that acknowledges the linkages between socioeconomic processes and environmental pressures and impacts, and designs policies to decouple economic activity from environmental pressures and impacts, requires a sophisticated and comprehensive knowledge base. The concept of industrial metabolism provides a sound conceptual base, and material flow accounting—including primary material inputs and outflows of waste and emissions—provides a well‐accepted operationalization. Studies presenting a comprehensive material flow account for a national economy are rare, especially for developing countries. Countries such as Lao People's Democratic Republic (Lao PDR or Laos) face dual objectives of improving the material standard of living of their people while managing natural resources sustainably and mitigating adverse environmental impacts from growing resource throughput. Our research fills a knowledge gap, presents a comprehensive account of material inputs and outflows of waste and emissions for the Lao PDR national economy, and applies the accounting approach for a low‐income economy in Asia. We present a material balance for the years 2000 and 2015. For this research, we used data from Lao PDR national statistics and the accounting guidelines of the European Statistical Office (Eurostat), which pioneered the use of material flow data as part of its official statistical reporting. We demonstrate the feasibility of the accounting approach and discuss the robustness of results using uncertainty analysis conducted with statistical approaches commonly used in the field of industrial ecology, including Gauss's law of error propagation and Monte Carlo simulation. We find that the fast‐changing scale and composition of Lao PDR material flows, waste, and emissions presents challenges to the existing policy capacity and will require investment into governance of changed patterns of material use, waste disposal, and emissions. We consider the data analysis sufficiently robust to inform such a change in policy direction.     

Mapping first to final uses for rare earth elements,globally and in the United States

Estimating the material flows of rare earth elements (REEs) is essential to understanding which industries are most vulnerable to potential REE supply disruptions which, in turn, may inform policy recommendations aimed at reducing the supply risk. However, the REEs are a group of mineral commodities characterized by highly uncertain estimates of supply and demand due to the REE market's complexity, opacity, and small size. In this study, a streamlined methodology was applied to map mineral commodity first-use to final-use applications and to estimate total requirements at the national level based on available industrial data for final-use finished goods. This analysis examines REEs both as a group and individually, showing that total US requirements are between 15% and 16.5% of world requirements for the year 2015, the latest year with the most complete information available. The findings shed light on US industrial capabilities by revealing the discrepancy between the types of REEs that go into US raw material consumption and those that are contained in embedded consumption. For instance, given the United States’ large oil refining industry, US raw material consumption of lanthanum is quite high. In contrast, US raw material consumption of neodymium is relatively low, whereas embedded demand is comparatively high. This reflects the lack of industrial capacity to process REE concentrates into magnet material combined with the US's high imports of products that contain rare earth permanent magnets.     

Urban Mining's Potential to Relieve China's Coming Resource Crisis

China's mineral resource consumption has gone through multiple increases since 1980, resulting in the inadequacy of important strategic resources and a high level of external dependence. Some developed countries have already reduced primary resources consumption through urban mining. Can China also break through the bottleneck of the resource shortage and continue its economic and social development through strengthening of urban mining? This article selected copper (Cu), aluminum (Al), lead (Pb), and iron (Fe) as case studies and established predictive models for metal demand, recycling, and stock, based on stock analysis, material flow analysis, and a life distribution model, and then analyzed the metabolism of the four resources and compared the environmental effects of three scenarios. The study indicates that the urban mining potential of Cu, Fe, Al, and Pb will attain 8.1, 711.6, 37.0, and 12.1 million tonnes, respectively, in 2040. Compared with 2010, the substitution rate (secondary metals substituting primary metals) of Cu and Fe increase by 25.4% and 59.9%, whereas external dependence decreases by 30.8% and 25.7%. However, substitution is not obvious regarding Al and Pb. The low resource scenario decreases resources use, which will reduce external dependence in the short term, whereas the strengthened recovery scenario increases resource recovery and has a larger effect in reducing external dependence in the long term. So, in line with urban mining in the future, China should change its environment and resource strategy, further strengthen layout and construction of urban mining demonstration bases, and encourage the use of recyclable resources to provide a better foundation for urban mining.     

Global Rare Earth In‐Use Stocks in NdFeB Permanent Magnets

The rare earth elements are indispensible in modern technology, especially in the applications of permanent magnets. Very little quantitative information is available on rare earth elements used in permanent magnets, however. This study looks back to 1983, when neodymium‐iron‐boron (NdFeB) permanent magnets were first manufactured, and reaches to 2007, when the market of permanent magnets was well developed. We draw on the historical data on permanent magnets from China, Japan, the United States, and Europe to provide the first estimates of global in‐use stocks for four rare earth elements—praseodymium (Pr), neodymium (Nd), terbium (Tb), and dysprosium (Dy)—in NdFeB permanent magnets. In‐use stocks amount to 62.6 gigagrams (Gg) Nd, 15.7 Gg Pr, 15.7 Gg Dy, and 3.1 Gg Tb; these stocks, if efficiently recycled, could provide a valuable supplement to geological stocks as they are almost four times the 2007 annual extraction rate of the individual elements.     

中国产业园区循环化改造应用关键物质流典型路径分析方法

产业园区循环化改造是我国在"十二五"期间和今后一个时期内的一项重要工作,也是在园区层面实施循环发展的主要内容。物质流分析(MFA)是产业生态学的核心分析方法,正在成为资源环境管理领域有效的分析工具。通过梳理物质流分析方法的发展历程,指出产业园区循环化改造应用物质流分析存在注重物质规模而忽视环境影响、黑箱过程不利定量研究、小区域研究适用性不强以及隐藏流造成的数据误差等方面问题,同时通过大量调查实践,认为园区循环化改造可从企业开展清洁生产、促进园区内和园区间的产业共生、加强园区资源循环基础设施建设3个领域入手,在将园区全部企业分为生产性企业、再生性企业和资源循环基础设施企业3种类型基础上,提出关键流概念及其识别思路,探索构建物质流路径归类评价方法框架,归纳出8条典型物质流路径,为提升园区物质流管理水平提供方法依据,并选取天津经济技术开发区作为典型案例进行研究,最后对我国产业园区循环化改造应用物质流分析方法进行了展望。     

The Physical Economy of the United States of America

The United States is not only the world's largest economy, but it is also one of the world's largest consumers of natural resources. The country, which is inhabited by some 5% of the world's population, uses roughly one‐fifth of the global primary energy supply and 15% of all extracted materials. This article explores long‐term trends and patterns of material use in the United States. Based on a material flow account (MFA) that is fully consistent with current standards of economy‐wide MFAs and covers domestic extraction, imports, and exports of materials for a 135‐year period, we investigated the evolution of the U.S. industrial metabolism. This process was characterized by an 18‐fold increase in material consumption, a multiplication of material use per capita, and a shift from renewable biomass toward mineral and fossil resources. In spite of considerable improvements in material intensity, no dematerialization has happened so far; in contrast to other high‐income countries, material use has not stabilized since the 1970s, but has continued to grow. This article compares patterns and trends of material use in the United States with those in Japan and the United Kingdom and discusses the factors underlying the disproportionately high level of U.S. per capita resource consumption.     

Dynamic Substance Flow Analysis of Neodymium and Dysprosium Associated with Neodymium Magnets in Japan

Recycling of neodymium and dysprosium is of great interest because of the rapid growth in their demand and limited supply of new resources. To promote recovery from end‐of‐life (EoL) products, it is desirable to quantify the recycling potentials of neodymium and dysprosium by their end use. This study characterized the substance flows of neodymium and dysprosium associated with neodymium magnets in Japan by conducting a dynamic substance flow analysis. A bottom‐up approach was employed in the analysis to estimate annual consumption by end use. Factors used in the analysis were the amounts of rare earth contents, weight of a magnet used for each product, adoption ratios of neodymium magnet usage in each product, and lifetime of products. It was found that the amount of neodymium entering use was approximately half of the domestic consumption; the balance existing in final products that were exported from Japan. The economic feasibility of recycling neodymium magnets was evaluated for their largest two end uses: driving motors in hybrid electric vehicles (HEVs) and compressors in air conditioners. It was found that recycling the neodymium magnets used in the driving motors has the potential for economic feasibility in Japan. The result showed that lower transportation costs for recovered magnets can make the recycling economically feasible regardless of the content rate and the price of metals. The future increase of EoL HEVs contributes to the feasibility of recycling with a profit in the upcoming years. Strategies for more profitable recycling are concentrating scrap motors or magnets among recycling factories or selecting specific factories that deal with EoL HEVs.     

Regional material flow accounts for China: Examining China's natural resource use at the provincial and national level

Over the last three decades, China has experienced the most dynamic economic development lifting living standards and resulting in fast‐growing use of natural resources. In the past, the focus has been on national MFA accounts which do not do justice to the second largest economy, home to 19% of the world population and having 30% of global material use. In this research, we calculate material extraction for China at the regional level during 1995–2015 using the most recent available statistical data and applying the most up‐to‐date international calculation methods. In particular, we combine a bottom‐up and top‐down approach for constructing the dataset of China's economically used Domestic Extraction (DEU) in an integrated way. This approach also improves the Chinese national material flow accounts and allows us to present a reliable database of DE of materials for China to date. Our new dataset provides the basis for calculating material footprints and environmental impacts of China's regions. The dataset enables us to evaluate regional resource efficiency trends in China. We find that during the past two decades, China's material use has grown strongly from 11.7 billion tonnes in 1995 to 35.4 billion tonnes in 2015. Material use has accelerated between 2000 and 2010 but slowed down between 2010 and 2015 reflecting the economic contraction caused by the Global Financial Crisis which reduced the global demand for China's manufacturing and a reorientation of China's economic policy settings toward quality of growth. Unsurprisingly, different regions play different roles in the supply chain of materials, achieving different economic performances resulting in very diverse material efficiency outcomes. This information is important to allow for a targeted policy approach to increase resource efficiency, reduce environmental impacts of resource use, and grow wellbeing in China with large positive implications for global sustainability. This study provides the basis for the development of relevant resource management policies for different regions in the future.     

稀土矿露天开采过程的污染及对资源和生态环境的影响

随着我国矿山开采活动的增加,矿山周边的生态环境面临前所未有的压力,并且产生了一系列的资源、生态与环境问题.本文介绍了我国典型稀土矿露天开采的主要方法和工艺流程,概述了稀土矿露天开采过程所产生的放射性污染、重金属、氟、氨氮和硫酸根污染问题,并且阐明了稀土矿开采对资源回收利用、周边大气、植物、水生态系统、土壤环境的影响与潜在的危害,为稀土矿区的污染综合整治和污染环境的生态修复提供科学依据.     

赣南稀土矿开发区生态环境遥感动态监测与评估

稀土矿业的发展在促进区域经济发展的同时,也对生态环境带来影响。为研究江西赣南稀土矿产开发及其对生态环境的影响,采用SPOT1/2/5、Landsat7和ALOS等多源遥感数据,对该区域2000—2010年稀土矿开发进行遥感动态监测。采用面向对象的方法对研究区进行生态系统分类,同时结合回溯法可较好地减少伪变化,并可快速地提取稀土矿开采区的变化信息。通过分析发现赣南稀土矿开采集中分布在几个主要的乡镇,从2000年至2010年这10年间整体上呈增加的趋势,但前5年主要体现为扩张,后5年复垦的力度在加强。新增的稀土矿矿区在开发过程中破坏的生态系统类型主要为林地,而废弃稀土矿区通过治理后主要恢复成耕地。稀土矿开采对植被覆盖、生物量、土地退化以及景观的破碎化都有一定的影响。同时稀土矿开采可能引发水体流失、山体滑坡等环境问题和风险。     

我国HEV废旧镍氢电池包中稀贵金属资源化利用环境效益分析

废旧动力电池包中含有丰富的镍、钴、稀土等稀贵金属,其资源化利用是实现混合动力汽车(Hybrid Electrical Vehicle,简称HEV)全生命周期绿色化管理的重要内容之一。随着HEV的不断发展,动力电池包在未来几年将逐渐进入批量报废阶段,其资源化利用的环境效益成为值得关注的问题。鉴于此,以丰田混合动力汽车镍氢电池包为研究对象,利用GREET模型和LIME值法测算出,相比于原生矿开采,单位废旧镍氢电池包中稀贵金属资源化利用所产生的环境效益为1083元;根据报废周期,对我国市场上现存的HEV镍氢电池包的未来报废情况进行预测。结果表明,这些电池包将从2018年开始迎来报废,在2021年达到报废高峰,至2024年基本完成报废;预计其稀贵金属资源化利用的环境效益,可累计达9421万元。提出了加强废旧动力电池回收体系和资源化利用体系建设的政策建议。     

Assessment of Trading Partners for China's Rare Earth Exports Using a Decision Analytic Approach

Chinese rare earth export policies currently result in accelerating its depletion. Thus adopting an optimal export trade selection strategy is crucial to determining and ultimately identifying the ideal trading partners. This paper introduces a multi-attribute decision-making methodology which is then used to select the optimal trading partner. In the method, an evaluation criteria system is established to assess the seven top trading partners based on three dimensions: political relationships, economic benefits and industrial security. Specifically, a simple additive weighing model derived from an additive utility function is utilized to calculate, rank and select alternatives. Results show that Japan would be the optimal trading partner for Chinese rare earths. The criteria evaluation method of trading partners for China''s rare earth exports provides the Chinese government with a tool to enhance rare earth industrial policies.     

Rare Earths from Mines to Metals: Comparing Environmental Impacts from China's Main Production Pathways

Over the past decade, China has supplied over 90% of global rare earths, and in doing so bore significant environmental burdens from processing its complex ores. In this study, we used life cycle assessment to quantify environmental impacts for producing 1 kilogram (kg) of 15 rare earth elements from each major production pathway. The scope of assessment included the largest rare earth oxide (REO) production chain in Bayan Obo, as well as lesser known production chains for bastnäsite in Sichuan and in‐situ leaching of kaolin clays in the Seven Southern Provinces of China. This was followed by assessing impacts from the three major metal refining processes: molten salt electrolysis, calciothermic reduction, and lanthanothermic reduction. Among 11 impact categories assessed, results were highest for human toxicity that ranged between 13.1 and 50.4 kg 1,4‐dichlorobenzene‐eq (equivalent)/kg of rare earth metal^?1, followed by eutrophication (0.04 to 1.26 kg phosphate‐eq/kg of rare earth metal^?1), abiotic depletion potential of fossil fuels (592 to 1,857 megajoules per kg of rare earth metal^?1), acidification (0.25 to 0.87 kg sulfur dioxide‐eq/kg of rare earth metal^?1), and global warming (39.1 to 109.6 kg carbon dioxide‐eq/kg of rare earth metal^?1) potentials. Regionally, impacts in Sichuan were lower across all key impact categories than in Bayan Obo: 32% lower for human toxicity, 67% lower for eutrophication, 58% lower for acidification, and 45% lower for global warming. A scenario analysis between the industry average and best available technologies revealed considerable potential to mitigate impacts across all production chains, particularly by improving waste treatment practices.     

Life cycle assessment of regeneration technology routes for sintered NdFeB magnets

The International Journal of Life Cycle Assessment - NdFeB magnetic material constitutes an important strategic material. With the rising demand for rare earth resources, the recycling and...     

Quantifying the responses of biological indices to rare macroinvertebrate taxa exclusion: Does excluding more rare taxa cause more error?

Including or excluding rare taxa in bioassessment is a controversial topic, which essentially affects the reliability and accuracy of the result. In the present paper, we hypothesize that biological indices such as Shannon–Wiener index, Simpson's index, Margalef index, evenness, BMWP (biological monitoring working party), and ASPT (Average Score Per Taxon) respond differently to rare taxa exclusion. To test this hypothesis, a benthic macroinvertebrate data set based on recent fifteen‐year studies in China was built for suppositional plot analyses. A field research was conducted in the Nansi Lake to perform related analyses. The results of suppositional plot simulations showed that Simpson's index placed more weight on common taxa than any other studied indices, followed by Shannon–Wiener index which remained a high value with the exclusion of rare taxa. The results indicated that there was not much of effect on Simpson's index and Shannon–Wiener index when rare taxa were excluded. Rare taxa played an important role in Margalef index and BMWP than in other indices. Evenness showed an increase trend, while ASPT varied inconsistently with the exclusion of rare taxa. Results of the field study also indicated that rare taxa had few impacts on the Shannon–Wiener index. By examining the relationships between the rare taxa and biological indices in our study, it is suggested that including the rare taxa when using BMWP and excluding them in the proposed way (e.g., fixed‐count subsampling) to calculate Shannon–Wiener index and Simpson's index could raise the efficiency and reduce the biases in the bioassessment of freshwater ecosystems.     

The Characteristics and Trends of Socioeconomic Metabolism in China

China has become the country with the largest resource use and has high levels of waste emissions that pose a great management challenge. To provide more details about environmental problems and to find effective solutions, this article analyzed the scale, structure, and trend of the socioeconomic metabolism in China during the period 1992–2014 based on economy‐wide material flow accounts (EW‐MFA), and predicted resource use during the period of the 13th Five‐Year Plan. The results of this study show that the scale of China's socioeconomic metabolism in China increased more than twofold, during 1992–2014. However, after 2011, with the economic slowdown, the growth rates of total material requirement (TMR), direct material input (DMI), and domestic processed output (DPO) began to decrease. China may reach an inflection point, but this point will probably not be approached before the year 2020. Material recycling (MR) has played an important role in improving resource productivity, improving it by 92.52 renminbi per tonne in 2014. Metallic minerals and fossil fuels are the main sources of hidden flow. Carbon dioxide (CO₂) emissions, construction waste, and agricultural emissions have become the major sources of DPO. Because of the 13th Five‐Year Plan, China may slow the growth rate of DMI and may save 10.26 gigatonnes of resources during 2015–2020. Resource productivity is predicted to increase by 15.91%. Imports and MR may play more important roles. These suggestions are made: (1) strengthening the recycling system; (2) stronger policies, especially in metallic mineral and fossil fuels; (3) developing management systems for CO₂ emissions, construction waste, and agricultural emissions; and (4) adjusting China's economic structure.     

Import‐based Indicator for the Geopolitical Supply Risk of Raw Materials in Life Cycle Sustainability Assessments

There is a growing concern over the security and sustainable supply of raw material among businesses and governments of developed, material‐intensive countries. This has led to the development of a systematic analysis of risk incorporated with raw materials usage, often referred as criticality assessment. In principle, this concept is based on the material flow approach. The potential role of life cycle assessment (LCA) to integrate resource criticality through broadening its scope into the life cycle sustainability assessment (LCSA) framework has been discussed within the LCA communities for some time. In this article, we aim at answering the question of how to proceed toward integration of the geopolitical aspect of resource criticality into the LCSA framework. The article focuses on the assessment of the geopolitical supply risk of 14 resources imported to the seven major advanced economies and the five most relevant emerging countries. Unlike a few previous studies, we propose a new method of calculation for the geopolitical supply risk, which is differentiated by countries based on the import patterns instead of a global production distribution. Our results suggest that rare earth elements, tungsten, antimony, and beryllium generally pose high geopolitical supply risk. Results from the Monte Carlo simulation allow consideration of data uncertainties for result interpretation. Issues concerning the consideration of the full supply chain are exemplarily discussed for cobalt. Our research broadens the scope of LCA from only environmental performance to a resource supply‐risk assessment tool that includes accessibility owing to political instability and market concentration under the LCSA framework.     

稀土钕元素的生物学效应及机制研究进展

本文主要就稀土钕元素的生物学效应及机制研究所取得的一些结果进行了讨论,对钕在植物体内的含量和分布,钕对植物种子萌发和生长发育、植物的矿质营养代谢、抗逆性和光合作用的影响等诸方面以及对微生物和动物影响的研究进行了总结,为其在农业上的广泛应用奠定理论基础。     

Domestic Yttrium Consumption Trends in Japan

Yttrium tends to occur in the same ore deposits as the lanthanides and exhibits similar chemical properties as rare earth elements. Yttrium sources are typically concentrated in China, and there are concerns about supply security. Yttrium is used in small, but essential, quantities in a variety of advanced industrial sectors, for example, in phosphors, advanced ceramics, optical glasses, and batteries. In terms of resource security, it is important to verify the domestic yttrium consumption trends. In order to characterize the domestic yttrium consumption trends in Japan, we tracked the historical yttrium consumption patterns from 2001 to 2011 by applying the bottom‐up approach and illustrated the recent domestic yttrium flow by using a substance flow analysis. The results showed that the total yttrium consumption has remained steady over 10 years, from 1,124 tonnes (t) in 2001 to 967 t in 2011. Recent consumption in 2011 was driven primarily by the use of yttrium in fluorescent lamps (462 t), nickel metal hydride batteries (185 t), and optic glasses (149 t).     

基于能值理论的有色金属矿产资源开采生态补偿机制

矿产资源为中国经济的高速增长提供了不竭的动力,但在其开采过程中也带来了诸多的环境问题。在当今资源、环境的约束下,如何采取适宜的量化方法来表征矿产资源开采所带来的生态环境损失,并在此基础上确定合理的生态补偿标准,成为了一项重要的研究课题。选取我国有色金属采选业为研究案例,并基于能值分析方法,核算了矿产资源开采过程中造成的直接、间接环境损失,提出了生态补偿指数,用以为生态补偿标准的制定提供参考依据。对能值分析指标的计算和分析结果表明,从可持续发展角度,生态补偿指数为89.18%,说明我国有色金属采选业的环境投入较高,需要的补偿费用较多;能值产出率为9.24,表明有色金属采选业的生产效率高;环境承载率为238,呈现高负荷状态,区域环境所承受的压力巨大;可持续发展指数为0.039,表明我国有色金属采选业处于不可持续状态,急需采取相关环境保护措施进行调整。从经济成本角度,我国有色金属采选业需要的生态环境补偿费用约为4.38×109元,现阶段征收的资源税费远低于生态恢复的治理费用,不能够覆盖生态修复治理成本。最后根据本文研究内容得出我国有色金属采选业面临的主要问题,分别从宏观角度、微观角度及长远角度3个方面给出了相应的政策建议。