Environmental, human health, and CO2 payback estimation and comparison of enhanced weathering for carbon capture using wollastonite
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[1] Fang Wang,et al. Multi-period optimization for CO2 sequestration potential of enhanced weathering using non-hazardous industrial wastes , 2023, Resources, Conservation and Recycling.
[2] K. Brooks. Rocks explained 2: Basalt , 2022, Geology Today.
[3] I. Power,et al. Impacts of dissolved phosphorus and soil-mineral-fluid interactions on CO2 removal through enhanced weathering of wollastonite in soils , 2022, Applied Geochemistry.
[4] A. Porporato,et al. The Carbon-Capture Efficiency of Natural Water Alkalinization: Implications For Enhanced weathering. , 2022, The Science of the total environment.
[5] A. Hawkes,et al. The life cycle environmental impacts of negative emission technologies in North America , 2022, Sustainable Production and Consumption.
[6] D. Beerling,et al. Environmental and health impacts of atmospheric CO2 removal by enhanced rock weathering depend on nations’ energy mix , 2022, Communications Earth & Environment.
[7] Wang Hong. A techno-economic review on carbon capture, utilisation and storage systems for achieving a net-zero CO2 emissions future , 2022, Carbon Capture Science & Technology.
[8] A. Hicks,et al. Evaluation of environmental and economic implications of a cold‐weather aquaponic food production system using life cycle assessment and economic analysis , 2022, Journal of Industrial Ecology.
[9] Jianzhuang Xiao,et al. Strategies to accelerate CO2 sequestration of cement-based materials and their application prospects , 2022, Construction and Building Materials.
[10] Fei Wang,et al. Regional carbon drawdown with enhanced weathering of non-hazardous industrial wastes , 2022, Resources, Conservation and Recycling.
[11] Alexis Laurent,et al. Identification of dissipative emissions for improved assessment of metal resources in life cycle assessment , 2021, Journal of Industrial Ecology.
[12] Jian-xin Zhao,et al. Recycling of carbon from the stagnant paleo-Pacific slab beneath Eastern China revealed by olivine geochemistry , 2021 .
[13] C. Hagke,et al. The influence of particle size on the potential of enhanced basalt weathering for carbon dioxide removal - Insights from a regional assessment , 2021 .
[14] R. Blust,et al. Deriving Nickel (Ni(II)) and Chromium (Cr(III)) Based Environmentally Safe Olivine Guidelines for Coastal Enhanced Silicate Weathering. , 2021, Environmental science & technology.
[15] H. Ramézani,et al. Assessment of CO2 adsorption capacity in Wollastonite using atomistic simulation , 2021, Journal of CO2 Utilization.
[16] Jinfeng Chang,et al. Potential CO2 removal from enhanced weathering by ecosystem responses to powdered rock , 2021, Nature Geoscience.
[17] M. Liao,et al. How silicon fertilizer improves nitrogen and phosphorus nutrient availability in paddy soil? , 2021, Journal of Zhejiang University-SCIENCE B.
[18] M. Devenney,et al. Calcium Carbonate Cement: A Carbon Capture, Utilization, and Storage (CCUS) Technique , 2021, Materials.
[19] G. Sonnemann,et al. Life cycle impact assessment methods for estimating the impacts of dissipative flows of metals , 2021, Journal of Industrial Ecology.
[20] W. Mo,et al. Environmental, human health, and economic implications of landfill leachate treatment for per- and polyfluoroalkyl substance removal. , 2021, Journal of environmental management.
[21] T. Amnuaylojaroen,et al. Impact of Biomass Burning on Ozone, Carbon Monoxide, and Nitrogen Dioxide in Northern Thailand , 2021, Frontiers in Environmental Science.
[22] R. Tan,et al. On life-cycle sustainability optimization of enhanced weathering systems , 2021 .
[23] Serenella Sala,et al. Mineral resource dissipation in life cycle inventories , 2021, The International Journal of Life Cycle Assessment.
[24] M. Mazzotti,et al. Life cycle assessment of carbon dioxide removal technologies: a critical review , 2021, Energy & Environmental Science.
[25] D. Kohlstedt,et al. Evolution of Microstructural Properties in Sheared Iron‐Rich Olivine , 2021, Journal of Geophysical Research: Solid Earth.
[26] C. Granada,et al. Use of Mineral Weathering Bacteria to Enhance Nutrient Availability in Crops: A Review , 2020, Frontiers in Plant Science.
[27] Wenzhen Wang,et al. Effect of wollastonite microfibers as cement replacement on the properties of cementitious composites: A review , 2020 .
[28] N. Nair,et al. Research initiatives on the influence of wollastonite in cement-based construction material- A review , 2020 .
[29] P. Renforth,et al. Ambient weathering of magnesium oxide for CO2 removal from air , 2020, Nature Communications.
[30] M. Lomas,et al. Potential for large-scale CO2 removal via enhanced rock weathering with croplands , 2020, Nature.
[31] R. Santos,et al. CO2 sequestration by wollastonite-amended agricultural soils – An Ontario field study , 2020, International Journal of Greenhouse Gas Control.
[32] Luca Zampori,et al. Accounting for the dissipation of abiotic resources in LCA: Status, key challenges and potential way forward , 2020, Resources, conservation, and recycling.
[33] D. Huisingh,et al. Advances and challenges of life cycle assessment (LCA) of greenhouse gas removal technologies to fight climate changes , 2020 .
[34] R. Santos,et al. Risk assessment of Ni, Cr, and Si release from alkaline minerals during enhanced weathering , 2020 .
[35] P. Renforth,et al. CO2 Removal With Enhanced Weathering and Ocean Alkalinity Enhancement: Potential Risks and Co-benefits for Marine Pelagic Ecosystems , 2019, Front. Clim..
[36] D. Manning,et al. Assessing the potential of soil carbonation and enhanced weathering through Life Cycle Assessment: A case study for Sao Paulo State, Brazil , 2019, Journal of Cleaner Production.
[37] W. Ashraf,et al. Effects of ground wollastonite on cement hydration kinetics and strength development , 2019, Construction and Building Materials.
[38] Pete Smith,et al. Impacts of enhanced weathering on biomass production for negative emission technologies and soil hydrology , 2019, Biogeosciences.
[39] Sudhirkumar V. Barai,et al. Comparative LCA of recycled and natural aggregate concrete using Particle Packing Method and conventional method of design mix , 2019, Journal of Cleaner Production.
[40] P. Renforth,et al. The negative emission potential of alkaline materials , 2019, Nature Communications.
[41] M. McManus,et al. Green chemistry for stainless steel corrosion resistance: life cycle assessment of citric acid versus nitric acid passivation , 2019, Materials Today Sustainability.
[42] Julie B. Zimmerman,et al. Cradle-to-Gate Greenhouse Gas Emissions for Twenty Anesthetic Active Pharmaceutical Ingredients Based on Process Scale-Up and Process Design Calculations , 2019, ACS Sustainable Chemistry and Engineering.
[43] Animesh Dutta,et al. Co-Benefits of Wollastonite Weathering in Agriculture: CO2 Sequestration and Promoted Plant Growth , 2019, ACS omega.
[44] M. Grosso,et al. Affordable CO2 negative emission through hydrogen from biomass, ocean liming, and CO2 storage , 2019, Mitigation and Adaptation Strategies for Global Change.
[45] E. Ercenk,et al. Crystallization kinetics of machinable glass ceramics produced from volcanic basalt rock , 2018, Journal of Non-Crystalline Solids.
[46] K. Isnugroho,et al. Characterization and utilization potential of basalt rock from East-Lampung district , 2018 .
[47] T. Amann,et al. Potential and costs of carbon dioxide removal by enhanced weathering of rocks , 2018 .
[48] I. Ioannou,et al. Carbon sequestration via enhanced weathering of peridotites and basalts in seawater , 2017 .
[49] Umberto Arena,et al. Life cycle assessment of natural and mixed recycled aggregate production in Brazil , 2017 .
[50] R. Freckleton,et al. Climate change mitigation: potential benefits and pitfalls of enhanced rock weathering in tropical agriculture , 2017, Biology Letters.
[51] D. Beerling,et al. Potential of global croplands and bioenergy crops for climate change mitigation through deployment for enhanced weathering , 2017, Biology Letters.
[52] O. Chavalparit,et al. Greenhouse Gases and Energy Intensity of Granite Rock Mining Operations in Thailand: A Case of Industrial Rock-Construction , 2016 .
[53] Stefan Seeger,et al. From laboratory to industrial scale: a scale-up framework for chemical processes in life cycle assessment studies , 2016 .
[54] Pete Smith. Soil carbon sequestration and biochar as negative emission technologies , 2016, Global change biology.
[55] S. Yari,et al. Risk Assessment of Exposure to Silica Dust in Building Demolition Sites , 2016, Safety and health at work.
[56] N. Nakicenovic,et al. Biophysical and economic limits to negative CO2 emissions , 2016 .
[57] Mark R. Lomas,et al. Enhanced weathering strategies for stabilizing climate and averting ocean acidification , 2015 .
[58] Peter A. Troch,et al. Climatic and landscape controls on water transit times and silicate mineral weathering in the critical zone , 2015 .
[59] Andrea L Hicks,et al. Life Cycle Payback Estimates of Nanosilver Enabled Textiles under Different Silver Loading, Release, And Laundering Scenarios Informed by Literature Review. , 2015, Environmental science & technology.
[60] P. Renforth,et al. Carbon dioxide efficiency of terrestrial enhanced weathering. , 2014, Environmental science & technology.
[61] R. Santos,et al. Susceptibility of mineral phases of steel slags towards carbonation: mineralogical, morphological and chemical assessment , 2013 .
[62] Till Zimmermann,et al. Critical materials and dissipative losses: a screening study. , 2013, The Science of the total environment.
[63] P. Renforth,et al. Enhanced chemical weathering as a geoengineering strategy to reduce atmospheric carbon dioxide, supply nutrients, and mitigate ocean acidification , 2013 .
[64] Duncan McLaren,et al. A comparative global assessment of potential negative emissions technologies , 2012 .
[65] P. Renforth,et al. The potential of enhanced weathering in the UK , 2012 .
[66] Claudia Fruijtier-Pölloth. The toxicological mode of action and the safety of synthetic amorphous silica-a nanostructured material. , 2012, Toxicology.
[67] P Renforth,et al. Silicate production and availability for mineral carbonation. , 2011, Environmental science & technology.
[68] C. Y. Tai,et al. Preparation of high surface area CaCO3 for SO2 removal by absorption of CO2 in aqueous suspensions of Ca(OH)2 , 2010 .
[69] D. Beerling,et al. Process‐based modeling of silicate mineral weathering responses to increasing atmospheric CO2 and climate change , 2009 .
[70] Jiang Chang,et al. Synthesis of nanocrystalline wollastonite powders by citrate-nitrate gel combustion method , 2009 .
[71] Stephan Kempe,et al. What is the maximum potential for CO2 sequestration by “stimulated” weathering on the global scale? , 2008, Naturwissenschaften.
[72] R. Lal,et al. Soil Carbon Sequestration Impacts on Global Climate Change and Food Security , 2004, Science.
[73] R. W. Le Maitre,et al. Igneous Rocks: A Classification and Glossary of Terms , 2002 .
[74] Klaus S. Lackner,et al. Carbon dioxide disposal in carbonate minerals , 1995 .
[75] W. Seifritz,et al. CO2 disposal by means of silicates , 1990, Nature.