Zhanyun Wang

Last Name

Wang

First Name

Zhanyun

ORCID

0000-0001-9914-7659

Organisational unit

01109 - Lehre Bau, Umwelt und Geomatik

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Publications 1 - 10 of 53

Deep Dive into Plastic Monomers, Additives, and Processing Aids
Wiesinger, Helene; Wang, Zhanyun; Hellweg, Stefanie (2021)
Environmental Science & Technology
A variety of chemical substances used in plastic production may be released throughout the entire life cycle of the plastic, posing risks to human health, the environment, and recycling systems. Only a limited number of these substances have been widely studied. We systematically investigate plastic monomers, additives, and processing aids on the global market based on a review of 63 industrial, scientific, and regulatory data sources. In total, we identify more than 10'000 relevant substances and categorize them based on substance types, use patterns, and hazard classifications wherever possible. Over 2'400 substances are identified as substances of potential concern as they meet one or more of the persistence, bioaccumulation, and toxicity criteria in the European Union. Many of these substances are hardly studied according to SciFinder (266 substances), are not adequately regulated in many parts of the world (1'327 substances), or are even approved for use in food-contact plastics in some jurisdictions (901 substances). Substantial information gaps exist in the public domain, particularly on substance properties and use patterns. To transition to a sustainable circular plastic economy that avoids the use of hazardous chemicals, concerted efforts by all stakeholders are needed, starting by increasing information accessibility.
Safe and Just Earth System Boundaries for Novel Entities
Diamond, Miriam L.; Wang, Zhanyun (2024)
Environmental Science & Technology Letters
Time to Break the “Lock-In” Impediments to Chemicals Management
Blumenthal, Jonathan; Diamond, Miriam L.; Hoffmann, Matthew; et al. (2022)
Environmental Science & Technology
Despite enormous national, regional, and global efforts on chemical management, the widespread use of hazardous chemicals continues in many parts of the world even after decades of there being well-known risks to public and/or ecosystem health. This continued supply and use, despite strong evidence of negative impacts, is not unique to chemicals management. In the field of climate change, the concept of "lock-in" has been used to explain the complex interactions among economic, social, technological, and political dynamics that reinforce global reliance on the extraction and use of fossil fuels. Learning from carbon "lock-in" phenomena, this Perspective explores the challenges of chemicals management from the perspective of lock-in through three case studies: paraquat, perfluorooctanesulfonic acid (PFOS), and asbestos. These case studies illustrate that most current chemicals management frameworks fail to address the concerns arising from this complex interplay by not involving all relevant stakeholder groups that are part of lock-in, from producers to consumers. This results in a relatively narrow consideration (e.g., only demand but not supply) of the effectiveness and consequences of regulations. We submit that to break lock-in and address the global threat of chemical pollution, current approaches to managing hazardous chemicals should be broadened to take a comprehensive approach to understanding and managing factors contributing to lock-in, notably both supply and demand on national and international scales.
Continuing large-scale global trade and illegal trade of highly hazardous chemicals
Zou, Hongyan; Wang, Tao; Wang, Zhong-Liang; et al. (2023)
Nature Sustainability
Pollution caused by anthropogenic chemicals contributes to interlinked planetary crises, together with climate change and biodiversity loss. One of the key treaties adopted to regulate the transboundary movements of hazardous chemicals is the Rotterdam Convention, which created a framework for countries to better handle the international trade of certain hazardous chemicals. To date, research examining the effectiveness of the Convention has been scarce. Here we analysed 66,156 trade records from the United Nations Comtrade database using a workflow that comprehensively addresses data-quality issues in the database. We found that for 46 listed chemicals, at least 64.5 megatonnes were traded in 2004–2019, and illegal trade was prevalent, reaching at least 25,324 trade records and 25.7 megatonnes. For over 70% of the listed chemicals, the Convention has played a positive role, but large-scale trade of some well-known chemicals such as tetraethyl and tetramethyl lead continues. Concerted efforts are warranted to improve how highly hazardous chemicals are traded globally, including enhancing enforcement of the Convention, addressing illegal trade and swiftly listing problematic chemicals (for example, chrysotile asbestos) in the Convention.
Net-zero transition of the global chemical industry with CO2-feedstock by 2050: feasible yet challenging
Huo, Jing; Wang, Zhanyun; Oberschelp, Christopher; et al. (2023)
Green Chemistry
Carbon capture, utilization and storage (CCUS) have been projected by the power and industrial sectors to play a vital role towards net-zero greenhouse gas emissions. In this study, we aim to explore the feasibility of a global chemical industry that fully relies on CO2 as its carbon source in 2050. We project the global annual CO2 demand as chemical feedstock to be 2.2-3.1 gigatonnes (Gt), well within the possible range of supply (5.2-13.9 Gt) from the power, cement, steel, and kraft pulp sectors. Hence, feedstock availability is not a constraint factor for the transition towards a fully CO2-based chemical industry on the global basis, with the exception of few regions that could face local supply shortages, such as the Middle East. We further conduct life cycle assessment to examine the environmental benefits on climate change and the trade-offs of particulate matter-related health impacts induced by carbon capture. We conclude that CO2 captured from solid biomass-fired power plants and kraft pulp mills in Europe would have the least environmental and health impacts, and that India and China should prioritize low-impact regional electricity supply before a large-scale deployment of CCUS. Finally, two bottom-up case studies of China and the Middle East illustrate how the total regional environmental and health impacts from carbon capture can be minimized by optimizing its supply sources and transport, requiring cross-sectoral cooperation and early planning of infrastructure. Overall, capture and utilization of unabatable industrial waste CO2 as chemical feedstock can be a feasible way for the net-zero transition of the industry, while concerted efforts are yet needed to build up the carbon-capture-and-utilization value chain around the world.
Are Fluoropolymers Really of Low Concern for Human and Environmental Health and Separate from Other PFAS?
Lohmann, Rainer; Cousins, Ian T.; DeWitt, Jamie C.; et al. (2020)
Environmental Science & Technology
Fluoropolymers are a group of polymers within the class of per- and polyfluoroalkyl substances (PFAS). The objective of this analysis is to evaluate the evidence regarding the environmental and human health impacts of fluoropolymers throughout their life cycle(s). Production of some fluoropolymers is intimately linked to the use and emissions of legacy and novel PFAS as polymer processing aids. There are serious concerns regarding the toxicity and adverse effects of fluorinated processing aids on humans and the environment. A variety of other PFAS, including monomers and oligomers, are emitted during the production, processing, use, and end-of-life treatment of fluoropolymers. There are further concerns regarding the safe disposal of fluoropolymers and their associated products and articles at the end of their life cycle. While recycling and reuse of fluoropolymers is performed on some industrial waste, there are only limited options for their recycling from consumer articles. The evidence reviewed in this analysis does not find a scientific rationale for concluding that fluoropolymers are of low concern for environmental and human health. Given fluoropolymers’ extreme persistence; emissions associated with their production, use, and disposal; and a high likelihood for human exposure to PFAS, their production and uses should be curtailed except in cases of essential uses.
Balancing New Approaches and Harmonized Techniques in Nano- and Microplastics Research
Mitrano, Denise Marie; Diamond, Miriam L.; Kim, Jae-Hong; et al. (2023)
Environmental Science & Technology Letters
Addressing chemical pollution in biodiversity research
Sigmund, Gabriel; Ågerstrand, Marlene; Antonelli, Alexandre; et al. (2023)
Global Change Biology
Climate change, biodiversity loss, and chemical pollution are planetary-scale emergencies requiring urgent mitigation actions. As these “triple crises” are deeply interlinked, they need to be tackled in an integrative manner. However, while climate change and biodiversity are often studied together, chemical pollution as a global change factor contributing to worldwide biodiversity loss has received much less attention in biodiversity research so far. Here, we review evidence showing that the multifaceted effects of anthropogenic chemicals in the environment are posing a growing threat to biodiversity and ecosystems. Therefore, failure to account for pollution effects may significantly undermine the success of biodiversity protection efforts. We argue that progress in understanding and counteracting the negative impact of chemical pollution on biodiversity requires collective efforts of scientists from different disciplines, including but not limited to ecology, ecotoxicology, and environmental chemistry. Importantly, recent developments in these fields have now enabled comprehensive studies that could efficiently address the manifold interactions between chemicals and ecosystems. Based on their experience with intricate studies of biodiversity, ecologists are well equipped to embrace the additional challenge of chemical complexity through interdisciplinary collaborations. This offers a unique opportunity to jointly advance a seminal frontier in pollution ecology and facilitate the development of innovative solutions for environmental protection.
Fluorinated Compounds in North American Cosmetics
Whitehead, Heather D.; Venier, Marta; Wu, Yan; et al. (2021)
Environmental Science & Technology Letters
Per- and polyfluoroalkyl substances (PFAS), a highly persistent and potentially toxic class of chemicals, are added to cosmetics to increase their durability and water resistance. To assess this potential health and environmental risk, 231 cosmetic products purchased in the U.S. and Canada were screened for total fluorine using particle-induced gamma-ray emission spectroscopy. Of the eight categories tested, foundations, mascaras, and lip products had the highest proportion of products with high total fluorine ≥0.384 μg F/cm2. Twenty-nine products including 20 with high total fluorine concentrations were analyzed using targeted LC-MS/MS and GC-MS. PFAS concentrations ranged from 22–10,500 ng/g product weight, with an average and a median of 264 and 1050 ng/g product weights, respectively. Here, 6:2 and 8:2 fluorotelomer compounds, including alcohols, methacrylates, and phosphate esters, were most commonly detected. These compounds are precursors to PFCAs that are known to be harmful. The ingredient lists of most products tested did not disclose the presence of fluorinated compounds exposing a gap in U.S. and Canadian labeling laws. The manufacture, use, and disposal of cosmetics containing PFAS are all potential opportunities for health and ecosystem harm. Given their direct exposure routes into people, better regulation is needed to limit the widespread use of PFAS in cosmetics.
Africa: renewables infrastructure avoids stranded assets
Wang, Zhanyun; Diamond, Miriam (2021)
Nature

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