Global perspectives and future research directions for the phytoremediation of heavy metal-contaminated soil: A knowledge mapping analysis from 2001 to 2020

doi:10.1007/s11783-021-1507-2

Front. Environ. Sci. Eng.

2022, Vol. 16

Issue (6) : 73 https://doi.org/10.1007/s11783-021-1507-2

REVIEW ARTICLE

Global perspectives and future research directions for the phytoremediation of heavy metal-contaminated soil: A knowledge mapping analysis from 2001 to 2020

Kehui Liu¹, Xiaojin Guan¹, Chunming Li^1,², Keyi Zhao¹, Xiaohua Yang¹, Rongxin Fu³, Yi Li¹(

), Fangming Yu¹(

)

¹. Key Laboratory of Ecology of Rare and Endangered Species and Environmental Protection (Ministry of Education), Guangxi Normal University, Guilin 541004, China
². School of Life Sciences, Fudan University, Shanghai 200438, China
³. Guangxi Normal University Library, Guangxi Normal University, Guilin 541004, China

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Abstract

• The overall global perspective of the PHMCS field was obtained.

• PHMCS research has flourished over the past two decades.

• In total, 8 clusters were obtained, and many new hot topics emerged.

• “Biochar,” “Drought,” “Nanoparticle,” etc., may be future hot topics.

• Five future directions are proposed.

In total, 9,552 documents were extracted from the Web of Science Core Collection and subjected to knowledge mapping and visualization analysis for the field of phytoremediation of HM-contaminated soil (PHMCS) with CiteSpace 5.7 R3 software. The results showed that (1) the number of publications increased linearly over the studied period. The top 10 countries/regions, institutions and authors contributing to this field were exhibited. (2) Keyword co-occurrence cluster analysis revealed a total of 8 clusters, including “Bioremediation,” “Arsenic,” “Biochar,” “Oxidative stress,” “Hyperaccumulation,” “EDTA,” “Arbuscular mycorrhizal fungi,” and “Environmental pollution” clusters (3) In total, 334 keyword bursts were obtained, and the 25 strongest, longest duration, and newest keyboard bursts were analyzed in depth. The strongest keyword burst test showed that the hottest keywords could be divided into 7 groups, i.e., “Plant bioremediation materials,” “HM types,” “Chelating amendments,” “Other improved strategies,” “Bioremediation characteristics,” “Risk assessment,” and “Other.” Almost half of the newest topics had emerged in the past 3 years, including “biochar,” “drought,” “health risk assessment,” “electrokinetic remediation,” “nanoparticle,” and “intercropping.” (4) In total, 9 knowledge base clusters were obtained in this study. The studies of Ali et al. (2013), Blaylock et al. (1997), Huang et al. (1997), van der Ent et al. (2013), Salt et al. (1995), and Salt (1998), which had both high frequencies and the strongest burst scores, have had the most profound effects on PHMCS research. Finally, future research directions were proposed.

Keywords Heavy metal-contaminated soil Hot topics Knowledge mapping analysis Knowledge base Phytoremediation

Corresponding Author(s): Yi Li,Fangming Yu

Issue Date: 11 October 2021

Cite this article:

Kehui Liu,Xiaojin Guan,Chunming Li, et al. Global perspectives and future research directions for the phytoremediation of heavy metal-contaminated soil: A knowledge mapping analysis from 2001 to 2020[J]. Front. Environ. Sci. Eng., 2022, 16(6): 73.

URL:

https://academic.hep.com.cn/fese/EN/10.1007/s11783-021-1507-2
https://academic.hep.com.cn/fese/EN/Y2022/V16/I6/73

Fig.1 Research framework.

Fig.2 Annual publication numbers and top 10 countries’ publication contributions.

Tab.1 The 10 countries/regions, institutions, authors, journals, and categories with the most PHMCS publications from 2001 to 2020

Fig.3 Cluster map of co-occurring keywords in PHMCS studies published from 2001 to 2020.

Fig.4 The 25 strongest keyword bursts (a), longest-duration keyword bursts (b), and most recent keyword bursts (c) in PHMCS studies.

Group labels	Highest keyword bursts	Longest duration keyword bursts	Most recent keyword bursts
(1) Remediation materials	Indian mustard (2001–2010, 46.9); Thlaspi caerulescen (2001–2010, 41.79); Hyperaccumulator Thlaspi caerulescen (2001–2010, 18.47); Arabidopsis helleri (2001–2010, 12.33); Fern (2002–2011, 19.6)	Durum wheat (2009–2016, 5.14); Indian mustard (2001–2010, 46.9); Thlaspi caerulescen (2001–2010, 41.79); Hyperaccumulator Thlaspi caerulescen (2001–2010, 18.47); Arabidopsis helleri (2001–2010, 12.33); Glomus intraradice (2001–2012, 4.77); Fern (2002–2011, 19.6); Berkheya coddii (2002–2011, 5.37); Holcus lanatus (2004–2011, 6.97)	Phytomanagement (2016–2020, 6.15); Assisted phytoremediation (2017–2020, 9.01); Giant reed (2017–2020, 6.95); Aided phytostabilization (2017–2020,8.48)
(2) HMs types	Nickel (2001–2005, 13.14); Zinc (2001–2008, 47.48); Lead phytoextraction (2001–2010, 14.56)	Zinc(2001–2008,47.48); Lead phytoextraction (2001–2010, 14.56); Zinc tolerance (2005–2012, 4.88);	Cadmium toxicity (2016–2020, 6.77); Potentially toxic element (2017–2020, 9.01); Cadmium stress (2017–2020, 8.29); Excess copper (2018–2020, 7.42)
(3) Chelates amendments	Chelating agent (2001–2010, 14.16); Phytochelatin (2002–2012, 11.7); EDTA (2003–2010, 15.46); Chelate (2003–2012, 15.07); EDD (2007–2013, 11.85)	Chelating agent (2001–2010,14.16); Phytochelatin (2002–2012, 11.7); EDTA (2003–2010, 15.46); Chelate (2003–2012, 15.07);	Organic amendment (2016–2020, 8.65)
(4) Other improve strategy	Phosphate (2003–2009, 10.5); Arbuscular mycorrhiza (2004–2011, 12.82); Biochar (2018–2020, 27.43)	Glomus mossease (2002–2011, 8.89); Arbuscular mycorrhiza (2004–2011,12.82); Sludge (2004–2011,7.19)	Biochar (218–2020, 27.43); Sp nov (2018–2020,7.05)
(5) Technical terminology	Transport (2001–2007, 13.85); Hyperaccumulation (2001–2008, 18.82); Absorption (2001–2008, 14.88); Uptake (2002–2009, 12.49); Heavy metal uptake (2002–2010, 11.58)	Hyperaccumulation (2001–2008, 18.82); Absorption (2001–2008, 14.88); Uptake (2002–2009, 12.49); Heavy metal uptake (2002–2010, 11.58); Leaching (2003–2011, 8.84);	Physiological response (2016–2020,9.52); Subcellar distribution (2018–2020, 10.05); Lipid peroxidation (2018–2020, 8.02); Spatial distribution (2018–2020, 7.05); Heavy metal pollution (2018–2020,6.68); Metal pollution (2018–2020, 6.3)
(6) Risk assessment	Health risk (2016–2020, 11.55); Risk assessment (2017–2020, 10.12)	–	Health risk (2016–2020, 11.55); Risk assessment (2017–2020, 10.12); Risk (2018–2020, 8.16); Health risk assessment (2018–2020, 6.67)
(7) Others	Population (2001–2008, 14.01); China (2016–2018, 11.21)	Population (2001–2008, 14.01)	Eletrokinetic remediation (2017–2020, 6.13); Drought (2017–2020, 6.1); Nanoparticle (2018–2020, 6.13); Intercropping (2018–2020,6.13)

Tab.2 Group analysis of the 25 strongest, longest-duration, and most recent keyword bursts in PHMCS studies

Fig.5 Co-citation cluster mapping in the PHMCS field from 2001 to 2020.

Tab.3 The most important cited references in the PHMCS field

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[1]	Kehui Liu, Jie Xu, Chenglong Dai, Chunming Li, Yi Li, Jiangming Ma, Fangming Yu. Exogenously applied oxalic acid assists in the phytoremediation of Mn by Polygonum pubescens Blume cultivated in three Mn-contaminated soils[J]. Front. Environ. Sci. Eng., 2021, 15(5): 86-.
[2]	Weichuan Qiao, Rong Li, Tianhao Tang, Achuo Anitta Zuh. Removal, distribution and plant uptake of perfluorooctane sulfonate (PFOS) in a simulated constructed wetland system[J]. Front. Environ. Sci. Eng., 2021, 15(2): 20-.
[3]	Ling Huang, Syed Bilal Shah, Haiyang Hu, Ping Xu, Hongzhi Tang. Pollution and biodegradation of hexabromocyclododecanes: A review[J]. Front. Environ. Sci. Eng., 2020, 14(1): 11-.
[4]	Mei Lei, Ziping Dong, Ying Jiang, Philip Longhurst, Xiaoming Wan, Guangdong Zhou. Reaction mechanism of arsenic capture by a calcium-based sorbent during the combustion of arsenic-contaminated biomass: A pilot-scale experience[J]. Front. Environ. Sci. Eng., 2019, 13(2): 24-.
[5]	Yi ZHONG, Jian WANG, Yizhi SONG, Yuting LIANG, Guanghe LI. Microbial community and functional genes in the rhizosphere of alfalfa in crude oil-contaminated soil[J]. Front Envir Sci Eng, 2012, 6(6): 797-805.

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