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How small a nanoplastic can be? A discussion on the size of this ubiquitous pollutant

Published online by Cambridge University Press:  03 October 2024

Bárbara Rani-Borges Open the ORCID record for Bárbara Rani-Borges [Opens in a new window]  and
Rômulo Augusto Ando
Bárbara Rani-Borges*
Affiliation:
Department of Fundamental Chemistry, Institute of Chemistry, University of São Paulo, USP, São Paulo, Brazil
Rômulo Augusto Ando
Affiliation:
Department of Fundamental Chemistry, Institute of Chemistry, University of São Paulo, USP, São Paulo, Brazil
*
Corresponding author: Bárbara Rani-Borges; Email: barbara.rani-borges@usp.br
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Abstract

Microplastics pollution is a widely recognized issue, although significant analytical challenges remain to be overcome in order to achieve a more comprehensive ecological understanding. The complex nature of this pollutant, with its variable physical and chemical properties, presents considerable challenges when it comes to establishing standardized methods for studying it. One crucial factor that influences its toxicity is particle size, yet even this parameter lacks a well-established framework, especially in the case of nanoplastics. Although the size range limits are already proposed in the literature, where the most acceptable values for microplastics are from 1 to 5,000 μm and for nanoplastics are from 1 to 1,000 nm, we propose narrowing these limits to 0.1–1,000 μm and 10–100 nm, respectively. We based our discussion on conceptual terminology, polymer structure and toxicity, highlighting the significance of accurately defining their size range. The standardization of these limits will allow the development of more efficient approaches to studying this pollutant, enabling a comprehensive understanding of its ecological consequences and potential risks.

Topics structure

Topic(s)

Sources and pathwaysTools, methods and measurement

Subtopic(s)

Analysis and interpretationDegradationDispersalUrbanWaste management

Keywords

microplasticnanoplasticfragmentationmolecular pollution

Information

Type
Perspective
Information
Cambridge Prisms: Plastics , Volume 2 , 2024 , e23
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Impact statement

This perspective article underscores the importance of precise size-range delineation for plastic particles, encompassing both nanoplastics and microplastics. It undertakes a comprehensive examination of the lower and upper size thresholds of nanoplastics and microplastics, considering both conceptual terminology and polymer structural aspects.

Transformation of microplastics and nanoplastics

The growing concern about plastic pollution has been the subject of debate worldwide. Microplastics have been extensively studied and recognized as a complex environmental problem. However, a new concern has recently emerged: nanoplastics. Although microplastics are mostly formed through mechanical fragmentation or degradation of larger plastics (secondary microplastics) (Kye et al., Reference Kye, Kim, Ju, Lee, Lim and Yoon2023), it is expected that the same process occurs with nanoplastics, which would be formed through continuous fragmentation of microplastics in the environment.

Weathering refers to the physical and chemical changes that plastics undergo due to factors such as sunlight (UV radiation), temperature variations, mechanical abrasion and chemical interactions with environmental substances (Wagner and Lambert, Reference Wagner and Lambert2018). These processes can cause degradation of the plastic particles, leading to changes in their structures and consequently to their properties (Pinlova and Nowack, Reference Pinlova and Nowack2024). As the exposure to adverse conditions persists, the prolonged stress on plastic polymers leads to the cleavage of intermolecular and intramolecular interactions (Kye et al., Reference Kye, Kim, Ju, Lee, Lim and Yoon2023), predominantly through mechanical fragmentation, photodegradation, thermal degradation and biodegradation (Julienne et al., Reference Julienne, Delorme and Lagarde2019; Tu et al., Reference Tu, Chen, Zhou, Liu, Wei, Waniek and Luo2020). Consequently, the progressive breakdown of polymer chains results in a reduction of particle size. Given the ongoing nature of this process, it is expected that plastics, microplastics and nanoplastics, will undergo continuous fragmentation and reduction in its size over time. This process can eventually result in the liberation of oligomers and monomers (Ganesh Kumar et al., Reference Ganesh Kumar, Anjana, Hinduja, Sujitha and Dharani2020; Biale et al., Reference Biale, La Nasa, Mattonai, Corti, Vinciguerra, Castelvetro and Modugno2021), which are considered new pollutants that have been poorly addressed (Hu et al., Reference Hu, Zhou, Chen, Zhang and Pan2023; Shi et al., Reference Shi, Wang, Wang, Qu, Jiang, Pan and Fang2023). This process is even more complex and is affected by multiple factors. According to Shi et al. (Reference Shi, Wang, Wang, Qu, Jiang, Pan and Fang2023), the kinetics of this process depends on the polymer type, molecular weight, degree of polymerization, morphology and surface density; however, research on these mechanisms remains limited.

Smaller particles possess unique properties that may influence their toxicity, bioavailability and potential to enter living organisms (Fang et al., Reference Fang, Luo and Naidu2023). The challenges related to the investigation of the impacts of nanoplastics go beyond the scope of this discussion article. The purpose of the present article is to focus on the conceptual and structural aspects of these pollutants as understanding the size limits of microplastics and nanoplastics is crucial for assessing their ecological and health implications. Defining an accurate size limit ensures comprehensive coverage of microplastic sizes, enables consistent measurement, reporting and comparability across studies, enhancing our understanding of their behavior and impacts to develop effective management strategies. Therefore, it is imperative to take certain conceptual considerations into account, particularly when it comes to the intricate physicochemical properties of polymers, before determining the minimum size at which a plastic particle can present. Establishing a clear limit for these particles remains a challenge, and this discussion aims to shed light on the final debate regarding plastic particle size. Ongoing technological advancements and interdisciplinary collaborations are key to resolving this debate and advancing our knowledge of such a ubiquitous pollutant.

Plastic particle size

Just as there remains a lack of consensus concerning methodologies for the sample collection, extraction and analysis of microplastics and nanoplastics, the classification of these particles in relation to their size also remains a subject of debate. In the scientific literature, numerous studies and environmental agencies’ guidelines propose different criteria for defining the size of microplastics. These definitions encompass a range of size thresholds, including particles up to 5 mm (Baker and Bamford, Reference Baker and Bamford2009; EFSA, 2016; GESAMP, Reference Kershaw2016, 2015), 2 mm (Ryan et al., Reference Ryan, Moore, Van Franeker and Moloney2009), 1 mm (GESAMP, 2015) or up to 500 μm (Gregory and Andrady, Reference Gregory, Andrady and Andrady2003). Besides that, the lower limits for microplastics also exhibit variability, with some studies suggesting no specific lower limit (Costa et al., Reference Costa, Ivar Do Sul, Silva-Cavalcanti, Araújo, Spengler and Tourinho2010; Koelmans et al., Reference Koelmans, Besseling, Shim, Bergmann, Gutow and Klages2015; Moore, Reference Moore2008; Ryan et al., Reference Ryan, Moore, Van Franeker and Moloney2009), while others propose a lower limit of 0.1 μm (EFSA, 2016), 1 μm (Andrady, Reference Andrady2015; Browne et al., Reference Browne, Galloway and Thompson2007; Desforges et al., Reference Desforges, Galbraith, Dangerfield and Ross2014; GESAMP, 2015; Ter Halle and Ghiglione, Reference Ter Halle and Ghiglione2021), 20 μm (Wagner et al., Reference Wagner, Scherer, Alvarez-Muñoz, Brennholt, Bourrain, Buchinger, Fries, Grosbois, Klasmeier, Marti, Rodriguez-Mozaz, Urbatzka, Vethaak, Winther-Nielsen and Reifferscheid2014) or 63 μm (Gregory and Andrady, Reference Gregory, Andrady and Andrady2003). Among all these terminologies, the most widely adopted is in between 1 and 5,000 μm.

Similar to microplastics, nanoplastics have been the subject of different classifications, as documented in the literature. However, it is worth noting that the extent of research and understanding surrounding nanoplastics is not as extensive as that of microplastics, primarily due to its emergence as a field of study in the last years. In general, the prevailing assumption among researchers is that nanoplastics can reach sizes as big as 1 μm with no lower limits (Fang et al., Reference Fang, Luo and Naidu2023) or range from 1 to 1,000 nm (Gigault et al., Reference Gigault, Halle, Baudrimont, Pascal, Gauffre, Phi, El Hadri, Grassl and Reynaud2018). Ter Halle and Ghiglione (Reference Ter Halle and Ghiglione2021) propose revising the lower limit for microplastics to 1 μm, aiming to avoid any overlap with the upper limit of nanoplastics which is also set at 1 μm. However, other classifications can be found because the size of nanoplastics is generally defined according to the size of the microplastics adopted in the studies.

Establishing a consistent size threshold to microplastics and nanoplastics

We propose the standardization of the maximum size of a microplastic up to 1 mm based on the fact that they mostly interact with high impact throughout the ecosystems when they are smaller than 1 mm. This can be evidenced by several study areas, like biology, medicine, pharmacy and biochemistry, where materials with different polymeric compositions are classified as microparticles if they are up to 1 mm in size (Ju and Chu, Reference Ju and Chu2019; Lengyel et al., Reference Lengyel, Kállai-Szabó, Antal, Laki and Antal2019; Oyewumi et al., Reference Oyewumi, Kumar and Cui2010; Stack et al., Reference Stack, Parikh, Wang, Wang, Xu, Zou, Cheng and Wang2019; Wang et al., Reference Wang, Zhang and Chu2014). Furthermore, studies suggest that plastic particles ranging from 100 to 300 μm are commonly found in the environment, while those exceeding 1 mm in size are less prevalent and not harmful to organisms (Klein et al., Reference Klein, Worch and Knepper2015; Laermanns et al., Reference Laermanns, Lehmann, Klee, Löder, Gekle and Bogner2021; Queiroz et al., Reference Queiroz, Pompêo, De Moraes, Ando and Rani-Borges2024; Rani-Borges et al., Reference Rani-Borges, Gomes, Maricato, Lins, Moraes, Lima, Côrtes, Tavares, Pereira, Ando and Queiroz2023). Accordingly, the environmental significance of larger particles (> 1 mm) is believed to have minimal environmental impact, a conclusion supported by extensive laboratory studies involving diverse aquatic and terrestrial organisms (Jacob et al., Reference Jacob, Besson, Swarzenski, Lecchini and Metian2020; Qiao et al., Reference Qiao, Mortimer, Richter, Rani-Borges, Yu, Heinlaan, Lin and Ivask2022). Regarding regulation, revising the threshold to 1 mm ensures that microplastics are genuinely micro in nature, enhancing clarity in terms of terminology, identification and classification by both scientific community and policymakers.

On the other hand, nanoplastics, as their name suggests, refer to plastic particles at the nanoscale. In 2018, Gigault et al. proposed an important definition for nanoplastics based on the colloidal behavior of particles with a size range of 1–1,000 nm, emphasizing the main differences and similarities between nanoplastics and manufactured nanomaterials to set the limits. As a material is reduced to dimensions on the nanoscale, typically between 1 and 100 nm, its properties can undergo significant changes (Roduner, Reference Roduner2006). These changes are a result of quantum and surface effects, which become more prominent when dealing with nanoscale structures. Multiple properties of a material can be affected when its size is reduced to the nanoscale (Hanachi et al., Reference Hanachi, Khoshnamvand, Walker and Hamidian2022). Some of the main observed changes include the optical, mechanical, electrical, thermal resistance, flexibility, chemical resistance, transparency and thermal and acoustic insulation properties, among others (Bond et al., Reference Bond, Ferrandiz-Mas, Felipe-Sotelo and Van Sebille2018; Li et al., Reference Li, Li, Ding, Song, Yang, Zhang and Guan2022; Shi et al., Reference Shi, Shi, Huang, Ye, Yang, Wang, Sun, Li, Shi, Xiao and Gao2024; Wang et al., Reference Wang, Gu, Dong, Chen, Jin, Gao, Ok and Gu2023; Yu et al., Reference Yu, Wu, Wang, Li, Chu, Pei and Ma2022). As an example, in the case of plastics, one of the most significant properties for determining their industrial applications is their mechanical properties (Jasso-Gastinel and Kenny, Reference Jasso-Gastinel and Kenny2017). In this regard, materials that are strong and rigid at the macroscale can become more flexible and deformable as its size is reduced (Guo and Wang, Reference Guo and Wang2019; Lutz and Grossman, Reference Lutz and Grossman2001). Size reduction introduces higher instability in the crystalline structures, making the materials more prone to deformations and fractures under lower levels of stress. Furthermore, the high surface-to-volume ratio of nanoplastics (Tallec et al., Reference Tallec, Blard, González-Fernández, Brotons, Berchel, Soudant, Huvet and Paul-Pont2019; Ter Halle and Ghiglione, Reference Ter Halle and Ghiglione2021) can result in notable alterations in mechanical properties, including hardness and strength. Thus, once a certain size is reached, it can be asserted that while the chemical structure retains the same composition, the properties that previously defined a particular type of plastic may have been compromised or lost entirely.

Regarding the limit sizes proposed by Gigault et al. (Reference Gigault, Halle, Baudrimont, Pascal, Gauffre, Phi, El Hadri, Grassl and Reynaud2018), we agree with all the reasoning presented, but we are proposing that in this discussion, the reviewing of the size limits for nanoplastics should be from 10 to 100 nm. First, considering the upper limit, the main point is that the nanomaterials are described as particles that possess at least one, and often two dimensions, and measuring less than 100 nm in size (Zhang et al., Reference Zhang, Ahmed, Wang and He2019). Hence, we propose that the upper threshold for nanoplastics should be set at 100 nm, which consequently establishes the lower threshold for microplastics at the same value. In relation to the lower limit size for nanoplastics, we believe that it is important to make a conceptual distinction between monomers, oligomers and plastics. It is well known that monomers are the basic units constituting polymers, whereas oligomers are short chains of monomers. For materials to be classified as plastics, they must have a well-defined polymeric architecture consisting of a long chain of repeated monomers (Young and Lovell, Reference Young and Lovell2011) (Figure 1). In addition, according to International Union of Pure and Applied Chemistry, “a polymer is a substance composed of molecules characterized by the multiple repetition of one or more species of atoms or groups of atoms (constitutional repeating units) linked to each other in amounts sufficient to provide a set of properties that do not vary markedly with the addition of one or a few of the constitutional repeating units” (IUPAC, 1974). Therefore, monomers and oligomers are essentially structures that do not meet the criteria to be considered plastics, as they do not exhibit a characteristic long polymeric chain and structurally lack the inherent properties of the material.

Figure 1. Configuration of polymer building units.

The proposed discussion focuses on the fragmentation product of nanoplastics. The main question is, at what point can these nanoparticles can still be considered as plastics? This is a complex question, as highlighted by Gigault et al. (Reference Gigault, Halle, Baudrimont, Pascal, Gauffre, Phi, El Hadri, Grassl and Reynaud2018), due to the fragmentation processes and their association with other species. Our point here, is that 1 nm definitely cannot be considered as the lower limit of a nanoplastic, and a bigger value must be set as the minimum threshold, because the size of a monomer is in the range of 1 nm, for example, considering PET (Venkatachalam et al., Reference Venkatachalam, Nayak, Labde, Gharal, Rao, Kelkar and Saleh2012), and therefore it cannot be considered as a “nanoplastic”. Due to the vast range of types of polymers, besides the number of monomers, it is commonly established for classification as a polymer a minimum range of repeated monomers combined with a threshold of 1,000 g/mol−1 or more (Hiemenz and Lodge, Reference Hiemenz and Lodge2007; Lechner et al., Reference Lechner, Gehrke and Nordmeier2014). The number of monomers criterion is based on the understanding that, with an adequate number of repeated monomers, the material begins to exhibit macroscopic properties characteristic of plastics, such as the formation of polymer chains and viscoelastic behavior. Therefore, considering various types of plastics extensively manufactured by the petrochemical industry (Table 1), taking as an example PET, which is the heaviest monomer of the series presented, to fulfill those requirements, it would give an oligomer of 5.45 nm.

Table 1. Molecular structure and weight of most produced polymers in the world

Hence, it can be concluded that the minimum size for a material to be classified as nanoplastics varies depending on its specific chemical composition. Therefore, taking PET as the lowest minimum reference, and considering the vast range of different chemical compositions of polymers, we suggest that any material smaller than 10 nm should no longer be considered as nanoplastics (Figure 2). In a field of study characterized by a significant lack of standardization, we recognize the importance of advocating for the establishment of guidelines that facilitate and enhance research pursuits. Standardization of research methodologies is a fundamental key to overcoming the complexities of characterizing nanoplastics. Establishing consistent protocols ensures reliability and comparability across studies, facilitating a more cohesive understanding of nanoplastics’ impacts and behavior. Misclassification of materials below 10 nm as nanoplastics could lead to challenges in monitoring, assessment and mitigation strategies, necessitating clear guidelines to address these potential issues.

Figure 2. Categorization of plastic debris according to size as applied in scientific literature and in the present study. As there is no international standard accepted worldwide, alternative categorizations are employed within the scientific literature.

In the study conducted by Ter Halle and Ghiglione (Reference Ter Halle and Ghiglione2021), the authors raised a pertinent concern regarding the term “micro(nano)plastics” and its potential drawbacks in understanding the impacts of these particles. Their research highlights the crucial role of particle size in determining the toxicity of micro- and nanoplastics. Thus, because of the variable toxicity influenced by particle size, it is essential to establish comprehensive size classification criteria based on the various facets and properties of plastics. This ensures a more accurate and effective assessment of the environmental and health implications associated with different sizes of plastic particles.

The implications of plastic’s outcome reveal that the analytical and ecological challenges associated with studying microplastics and nanoplastics will intensify as these particles diminish in size. Given the estimated quantity of plastic existing in the environment and the inescapable process of material fragmentation, it is crucial for research to encompass the examination of degradation byproducts stemming from this material. In essence, the fragmentation of nanoplastics not only perpetuates the environmental burden of plastic pollution but also presents a new dimension of contamination at the molecular level.

Conclusion

Since the presence and impacts of microplastics in the environment began to be studied, establishing standardized protocols for studying this diverse and complex pollutant has been a significant challenge. The absence of universally accepted standards has resulted in noncomparable studies and communication difficulties within the scientific community. Size classification emerges as a crucial factor concerning plastic particles. Currently, there is still no widely agreed-upon classification, despite most studies adopting similar categorizations. These classifications lack consistency with respect to the conceptual and structural definitions of the material. In this discussion, we present arguments supporting the implementation of size limits for plastic particles, encompassing both nano, as particles in the size range of 10–100 nm, and microplastics in the size range of 100–1,000 nm. By precisely defining these limits, especially the lower thresholds for nanoplastics and the upper limits for microplastics, researchers can more effectively assess the risks associated with these plastic particles and develop appropriate mitigation strategies. This holistic approach allows for a deeper exploration of the intricate pathways through which microplastics and nanoplastics interact with ecosystems, including their potential to be transformed into single molecules.

Open peer review

To view the open peer review materials for this article, please visit http://doi.org/10.1017/plc.2024.25.

Data availability

No data were used for the research described in the article.

Acknowledgments

The authors would like to thank the Sao Paulo State Research Support Foundation (FAPESP) (Process 2022/15586-0 and 2022/11983-4).

CRediT authorship contribution statement

Bárbara Rani-Borges: Conceptualization, writing – original draft, writing – review and editing. Rômulo Augusto Ando: Conceptualization, writing – original draft, writing – review and editing.

Declaration of Competing interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this article.

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Figure 0

Figure 1. Configuration of polymer building units.

Figure 1

Table 1. Molecular structure and weight of most produced polymers in the world

Figure 2

Figure 2. Categorization of plastic debris according to size as applied in scientific literature and in the present study. As there is no international standard accepted worldwide, alternative categorizations are employed within the scientific literature.

Author comment: How small a nanoplastic can be? A discussion on the size of this ubiquitous pollutant — R0/PR1

DOI: https://doi.org/10.1017/plc.2024.25.pr1 [Opens in a new window]
Bárbara Rani-Borges [Opens in a new window] Department of Fudamental Chemistry, University of São Paulo Institute of Chemistry, Brazil
Revision round: 0
Role: author

Comments

Dear editor of Cambridge Prism: Plastics,

We wish to submit a Perspective Manuscript entitled “How small a microplastic can be? A discussion on the size of this ubiquitous pollutant” for consideration in Cambridge Prism: Plastics journal. We believe that this discussion is urgent due to lack of standardization regarding the size limits of microplastics, what generally leads to misconceptions and controversies in the literature, especially in the case of term “nanoplastics”. This is an unprecedented debate of a fundamental aspect to be considerate about microplastics and we strongly believe it is appropriate for the Cambridge Prism: Plastics journal audience.

The size of microplastic particles plays a crucial role in determining their toxicity, but there is currently no established framework to define this parameter. The lack of standardized size definitions creates scientific challenges and makes it difficult to compare studies. As a result, our understanding of the behavior and effects of microplastic particles is limited, which hampers the development of effective environmental management strategies. This paper aims to highlight the importance of accurately defining the size range of microplastic particles. We examine the question of the minimum and maximum sizes plastic particles (nano and microplastics) considering both conceptual terminology and polymer structure. We argue that precise size definition is crucial for a comprehensive ecological understanding, enabling better assessment of their toxicity and potential risks. Instead, we propose the adoption of more efficient approaches to studying microplastics. By addressing the issue of size classification, researchers can overcome the limitations caused by the absence of standards, promoting comparability and facilitating progress in the field.

This perspective manuscript aligns well with the scope and objectives of Cambridge Prism: Plastics, advancing knowledge in microplastic pollution research by providing insights, proposing strategies, and offering intellectual depth. The study appeals to a broad readership and brings a new perspective on the impact of physicochemical factors on microplastic particles. We believe our manuscript will significantly contribute to the field and facilitate the development of effective strategies to address microplastic pollution.

Thank you for considering our submission.

Sincerely,

Bárbara Rani-Borges and Rômulo A. Ando

Recommendation: How small a nanoplastic can be? A discussion on the size of this ubiquitous pollutant — R0/PR2

DOI: https://doi.org/10.1017/plc.2024.25.pr2 [Opens in a new window]
John Virdin [Opens in a new window] Nicholas School of the Environment, Duke University, United States
Date of review:  26 March 2024
Revision round: 0
Role: Handling Editor
Recommendation/decision: major-revision

Comments

Both reviewers found the paper interesting and novel to set a lower threshold for nanoplastics, but suggested a number of revisions for the authors’ considerations. In particular, before the paper can be accepted for publication, it would be important to:

Consider and justify as needed the suitability of generalizations made from specific information or potentially focus on specific polymers (R1 recommendation), including revision of the text on the degradation mechanisms (L26-33), clearer justification for the higher threshold for microplastics (L49-56), use of Hiemens and Lodge (2007), considerations of the Flory theory and derivations to estimate polymer chain volume, etc., per comments from R1; and

Review for style and presentation, to ensure a discursive style rather than reading as a “news report”, with an in-depth discussion of the insights provided from the research, and clarifying when size may or may not be the key issue.

We would be pleased to consider a revised version that considers the comments from the Reviewers.

Comments from Reviewer #1:

The paper “How small a microplastic can be? A discussion on the size of this ubiquitous pollutant” has an interesting approach. The authors took into consideration some molecular fundamentals to support a proposal for a lower threshold in the definition of nanoplastics.

A strong point is the interesting and original, as far as I know, attempt to build reasoning to set a lower threshold for nanoplastics. The weak point is that to build the reasoning, the authors made unsuitable generalizations from specific information. The manuscript can be significantly improved by considering some fundamentals of polymer science and using established data from the fields of polymer synthesis and polymer degradation to estimate the polymer and oligomer sizes.

Suggestions and questions

1. Page 2, lines 26-30: The statement “As the exposure to adverse conditions persists, the prolonged stress on plastic polymers leads to the cleavage of chemical bonds (Kye et al., 2023), resulting on the liberation of monomers and oligomers (A. et al., 2020)” make it seems that there is a direct relation between the breakage of the bonds and the formation of monomers and oligomers. This only happens when the polymer and conditions are prone to the mechanism of depolymerization. Depolymerization is actually the aim of the current research efforts for chemical recycling, where researchers want to obtain monomers and dimers from waste using specific conditions and catalysts. However, this is not the case for most polymers in the environmental conditions for degradation, which are the conditions that must be considered for the manuscript framework. In most polymers, the breakage leads to smaller polymer chains and then, at an advanced degradation level, the significant formation of oligomers and smaller “mers.” I suggest the rewriting of the sentence to capture the proper degradation mechanism.

2. Page 2, lines 30-31: Regarding the statement “predominantly from the most susceptible portion of the polymer chains, which are the chain ends”, this is only true, as I said in the suggestion before, for the depolymerization mechanism, which is not true for most polymers.

3. Page 2, lines 31-33: Regarding the statement, “This phenomenon is commonly referred to as plastic fragmentation”, I suggest the authors reconsider it. As far as I know, the cleavage of chemical bonds and the formation of oligomers to monomers is not commonly referred to as fragmentation. I suggest adding solid references to back this claim, or rephrasing.

4. Page 3, lines 49-56: I am confused about the authors' proposition to set the higher threshold for microplastics to 1 mm. I would like to see the reference for the micropollutant definition based on the visual perception presented in the paper. Additionally, the authors used a definition based on visual perception to point to a contradiction in using the prefix micro to describe something visually observed. Still, they then proposed the threshold of 1mm, which is also visualizable with the human eyes. My conclusion is that I did not capture the message the authors wanted to convey; therefore I ask for a rewriting for a more explicit message.

5. Page 5, lines 10-21: This excerpt has several statements that deserve reference. Please add them accordingly.

6. Page 5, lines 40-44: The reasoning from the size of the carbon-carbon bond and the size of the nanoplastics, just multiplying the bond size by the number of repetitions, is questionable because a polymer chain will never be a straight line. I suggest the authors consider Flory theory and derivations to estimate the polymer chain volume and dimensions to make better assumptions about the size of the nanoplastic.

7. Page 5, line 47: The excerpt “threshold of 1,000 g/mol or more” misrepresents the reference Hiemens and Lodge 2007. The reference stated, “For now, we assume that a polymer molecule has a molecular weight M, which can be anywhere in the range 10^3—10^7 or more.” This statement does not indicate the usage of the lower limit of 10^3 for all polymers. The minimum size for a polymer depends not only on the molar weight but also on other features like conformation energy, intermolecular interactions, and monomer molar weight, among others. All of these features vary with the type of monomer/polymer, so the generalization cannot be made the way the authors did. As I said in the beginning, this is one of the examples of a broad generalization of specific information. As a general advice, the authors could have a better manuscript if they chose only a few specific polymers, or maybe only a very relevant one, like the low-density polyethylene, to use the specific information to build more accurate numbers and assumptions.

8. Page 6, lines 43-48: The field of polymer synthesis is very consolidated, with thousands of papers; I recommend using it to check the information, like the one on PET, with just five monomers being considered a polymer. The same goes for the polyethylene in the same paragraph.

Comments from Reviewer #2:

the report titled “How small a microplastic can be? A discussion on the size of this ubiquitous pollutant” reads interesting, to define the nanoplastics at > 10 nm, which is needed for academics. However, the reviewer also has some concerns for their consideration, please

1. it reads like a news report, rather than a scientific literature. The discussion in depth should be provided to support any statement with insights.

2. For example, the statements of “Hence, it can be concluded that the minimum size for a material to be classified as nanoplastics should not adhere to a universal rule, as it varies depending on its specific chemical composition. However, in a field characterized by a significant lack of standardization, we recognize the importance of advocating for the establishment of guidelines that facilitate and enhance research pursuits. Therefore, we suggest that any material smaller than 10 nm should no longer be considered as nanoplastics (Figure 2)” is confused. a clear logic should be followed.

3. Another example is “Consequently, a chain of PE with 35 monomers has a length of 10.78 nm”, which is based on the linear structure. If branched or cross-linked, the size is different.

4. the debates on the boundary of 1 um/0.1 um, 1 mm/ 5 mm for nanoplastics-microplastics are still ongoing. Where the size is not the key issue, rather than regulation or policy issue, which should be clarified.

Decision: How small a nanoplastic can be? A discussion on the size of this ubiquitous pollutant — R0/PR3

DOI: https://doi.org/10.1017/plc.2024.25.pr3 [Opens in a new window]
Steve Fletcher [Opens in a new window] School of Environment, Geography and Geosciences, University of Portsmouth, United Kingdom of Great Britain and Northern Ireland
Revision round: 0
Role: Editor in Chief
Recommendation/decision: major-revision

Comments

No accompanying comment.

Author comment: How small a nanoplastic can be? A discussion on the size of this ubiquitous pollutant — R1/PR4

DOI: https://doi.org/10.1017/plc.2024.25.pr4 [Opens in a new window]
Bárbara Rani-Borges [Opens in a new window] Department of Fudamental Chemistry, University of São Paulo Institute of Chemistry, Brazil
Revision round: 1
Role: author

Comments

Dear Editor-in-Chief Prof. Steve Fletcher and handling editor John Virdin,

Herewith we are submitting our revised manuscript entitled “How small a nanoplastic can be? A discussion on the size of this ubiquitous pollutant”.

I, along with my coauthor Rômulo Augusto Ando, would like to thank you for your communication concerning our manuscript submitted to Cambridge Prisms: Plastics. The comments provided by the reviewers were highly constructive and have enabled us to improve the manuscript.

We have carefully considered the reviewers' suggestions and implemented improvements throughout the text, including revising the manuscript title. We hope that we have now prepared a better, more balanced account of our work, and we hope that the revised manuscript will be considered appropriate for publication in Cambridge Prisms: Plastics.

We would like to take this opportunity to thank the reviewers for the kind work, careful review and constructive suggestions with regard to our manuscript. We responded to all the comments and made all of the requested changes. Those changes are highlighted in blue in the tracked version of the manuscript and we explained in detail how we responded to each of the comments.

Both authors have read and approved the revised manuscript for submission to Cambridge Prisms: Plastics.

Sincerely,

Bárbara Rani-Borges and Rômulo Ando,

University of São Paulo São Paulo, Brazil

E-mail: barbara.rani-borges@usp.br

Recommendation: How small a nanoplastic can be? A discussion on the size of this ubiquitous pollutant — R1/PR5

DOI: https://doi.org/10.1017/plc.2024.25.pr5 [Opens in a new window]
John Virdin [Opens in a new window] Nicholas School of the Environment, Duke University, United States
Date of review:  05 June 2024
Revision round: 1
Role: Handling Editor
Recommendation/decision: accept

Comments

We recognize the efforts and responses to revise the manuscript, and are happy to accept it for publication. One of the reviewers made one final and minor suggestion that we would share for the authors' consideration in finalizing the manuscript for publication:

“I have only one last comment on the new text. The answer to my question number 4 (Page 5 of 39) is a good one, conveying a sound message for the superior threshold of 1 mm. The only remaining point is the initial sentence and the associated references. I checked the definition of micropollutants in both the references provided by the authors, and they state that a micropollutant is defined by the concentration and not by the size, different from what the authors stated in “By definition, micropollutants are substances that exist on a maximum scale of µg/L (Anielak et al., 2022; Bertram et al., 2022) and, therefore, are practically invisible to the human eye due to their SIZE and concentration.” Since the text that follows the initial sentence approaches only a matter of size, it makes no sense to keep a definition based on concentration, according to the references provided by the authors. I suggest removing the initial sentence and keeping the rest of the paragraph as it is.”

We pass this along for consideration by the authors of removing the sentence per recommendation of one of the reviewers, prior to final publication.

But given the effort in the revisions, we’re happy to accept this paper for publication.

Decision: How small a nanoplastic can be? A discussion on the size of this ubiquitous pollutant — R1/PR6

DOI: https://doi.org/10.1017/plc.2024.25.pr6 [Opens in a new window]
Steve Fletcher [Opens in a new window] School of Environment, Geography and Geosciences, University of Portsmouth, United Kingdom of Great Britain and Northern Ireland
Revision round: 1
Role: Editor in Chief
Recommendation/decision: accept

Comments

No accompanying comment.