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Abstract
Discarded plastic wastes are slowly degrading into smaller parts, namely microplastics, that can be easily transported to oceans by water streams. In vast, salty, and sunny environments, they degrade even faster and are subject to come back in the water network used for drinking or industrial water in the form of nearly indetectable objects: nanoplastics. Once in busy buffers such as wastewaters, nanoplastics will tend to aggregate to form tertiary microplastics formed of single or multiple types of plastics and potentially host other materials ranging from organics and metals to bacteria and viruses. Their nature, random shape, and various size are at the origin of nuclei merging together or with other objects. Two particles at a close distance from each other can either attract or repulse themselves depending on their nature and constitution. At very short distances, Van der Waals forces are predominant and a measure of them is given by the so-called Hamaker constant. We propose to predict this aggregation by estimating the Hamaker’s constant.
Keywords
Nanoplastics
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Wastewater
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Hamaker constant
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Complex refractive index
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Spectroscopy
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Kai-Erik Peiponen, Matthieu Roussey.
Prediction of nanoplastics aggregation in wastewaters.
Emerging Contaminants and Environmental Health, 2023, 2(3): 12 DOI:10.20517/wecn.2023.26
| [1] |
Zhang Y,Allen S,Gao T.Atmospheric microplastics: a review on current status and perspectives.Earth-Science Reviews2020;203:103118
|
| [2] |
Coyle R,Driscoll KO.Microplastics in the marine environment: a review of their sources, distribution processes, uptake and exchange in ecosystems.Case Stud Chem Environ Eng.2020;2:100010
|
| [3] |
Liu W,Liu H.A review of the removal of microplastics in global wastewater treatment plants: characteristics and mechanisms.Environ Int2021;146:106277
|
| [4] |
Yang L,Kang S,Wu C.Microplastics in soil: a review on methods, occurrence, sources, and potential risk.Sci Total Environ2021;780:146546
|
| [5] |
Garaba SP,Slat B.Sensing ocean plastics with an airborne hyperspectral shortwave infrared imager.Environ Sci Technol2018;52:11699-707
|
| [6] |
Faltynkova A,Wagner M.Hyperspectral imaging as an emerging tool to analyze microplastics: a systematic review and recommendations for future development.2021;1:13
|
| [7] |
Peiponen K,Hrovat B.Sorting microplastics from other materials in water samples by ultra-high-definition imaging.J Eur Opt Society-Rapid Publ2023;19:14
|
| [8] |
Sun Y,Ruf C.Effects of microplastics and surfactants on surface roughness of water waves.Sci Rep2023;13:1978 PMCID:PMC9898532
|
| [9] |
Atugoda T,Wijesekara H.Interactions between microplastics, pharmaceuticals and personal care products: implications for vector transport.Environ Int2021;149:106367
|
| [10] |
Wang Y,Wang F.Influence of typical clay minerals on aggregation and settling of pristine and aged polyethylene microplastics.Environ Pollut2023;316:120649
|
| [11] |
Wang CQ,Gu GH,Lin QQ.Interfacial interactions between plastic particles in plastics flotation.Waste Manag2015;46:56-61
|
| [12] |
Swart B,John Chew Y.Microbubble-microplastic interactions in batch air flotation.Chem Eng J2022;449:137866
|
| [13] |
Gigault J,Baudrimont M.Current opinion: what is a nanoplastic?.Environ Pollut2018;235:1030-4
|
| [14] |
Pradel A,Gigault J.The environmental fate of nanoplastics: what we know and what we need to know about aggregation.NanoImpact2023;29:100453
|
| [15] |
Magalhães S,Romano A,Rasteiro MDG.Extraction and characterization of microplastics from portuguese industrial effluents.Polymers2022;14:2902 PMCID:PMC9318256
|
| [16] |
Singh US. Characteristics and treatment of pulp and paper mill effluents-a review. Available from: https://www.erpublication.org/published_paper/IJETR2943.pdf. [Last accessed on 12 Jul 2023]
|
| [17] |
Teow YH,Ho KC.Treatment of semiconductor-industry wastewater with the application of ceramic membrane and polymeric membrane.J Cleaner Prod2022;337:130569
|
| [18] |
Dzyaloshinskii IE,Pitaevskii LP. Van der waals forces in liquid films. Available from: http://jetp.ras.ru/cgi-bin/dn/e_010_01_0161.pdf. [Last accessed on 12 Jul 2023]
|
| [19] |
Fiedler J,Persson C.Full-spectrum high-resolution modeling of the dielectric function of water.J Phys Chem B2020;124:3103-13
|
| [20] |
Jansen C,Koch M.Terahertz spectroscopy of polymers.In: Peiponen K-E, Zeitler A, Kuwata-Gonokami M, editors. Terahertz Spectroscopy and Imaging. Berlin: Springer; 2013. p. 327-53.
|
| [21] |
Han S,Kim K,You K.Quantitative analysis of attachment time of air bubbles to solid surfaces in water.Langmuir2021; 37:616-26.
|
| [22] |
Jiang K.Temperature and size-dependent Hamaker constants for metal nanoparticles.Nanotechnology2016;27:345710
|
| [23] |
Li C,Palmai M,Baveye PC.Colloidal stability and aggregation kinetics of nanocrystal CdSe/ZnS quantum dots in aqueous systems: effects of ionic strength, electrolyte type, and natural organic matter.SN Appl Sci2022;4:101
|
| [24] |
née Korvela PT,Penttilä MS. et al. EU’s upcoming microplastics regulation: technology’s possibilities to answer to the potential broader implications. Available from: https://researchportal.helsinki.fi/en/publications/eus-upcoming-microplastics-regulation-technologys-possibilities-t. [Last accessed on 12 Jul 2023]
|
