Exploring Humic Acid as an Efficient and Selective Adsorbent for Lead Removal in Multi-Metal Coexistence Systems: A Review
Abstract
:1. Introduction
2. Research Status of Molecular Structure of HA
2.1. Characterization Methods of HA Structure
2.1.1. Characterization of HA Elemental Composition
2.1.2. Characterization of HA Functional Groups
2.2. HA Fractionation
2.2.1. Methods of HA Fractionation
2.2.2. The Potential Impact of HA Fractionation on the Environment
2.3. The Interaction between Typical Structures of HA and Heavy Metal Ions
- (1)
- Electrostatic interaction: HA exhibits diverse pKa values, functioning as a weak acid and a strong acidic ion-exchange as a polyelectrolyte. This characteristic allows for the formation of diffuse double layers around charged particles, facilitating heavy metal adsorption [55,56]. HISS standards suggest that the content of –COOH in HA significantly exceeds that of hydroxyl groups, and their dissociation occurs at pH > 4.4, resulting in a predominantly negatively charged surface on HA [57]. This facilitates electrostatic reactions with heavy metals. At higher pH values (>9.5), –OH become more prone to metal complexation as they are easily protonated. The increase in pH effectively deprotonates carboxylic groups, enhancing their binding with positively charged metals [58]. Studies have shown that hydroxyl and carboxyl groups in HA chelate with heavy metals, enhancing the adsorption rate [59]. Zhao et al. [44] proposed that phenolic and carboxylic groups are the primary adsorption sites for Pb2+, while, according to Kinnibrugh’s research [60], different functional groups exhibit varying binding affinities with metal ions, with carboxyl groups showing significant binding capacities: Pb2+ > Cu2+ > Cd2+. Beyond active sites, structural features also influence the complexation of heavy metals by HA [61].
- (2)
- Carboxyl Coordination and Phenolic Hydroxyl Coordination: The carboxyl functional groups (–COOH) in HA are important structures involved in the complexation with heavy metal ions. Heavy metal ions typically form coordination bonds with hydroxy oxygen in carboxyl groups or oxygen in carboxyl groups, resulting in the formation of stable complexes. This coordination interaction forms the basis for the selective adsorption of heavy metal ions by HA. The phenolic hydroxyl functional groups (–OH) in HA are also key structures involved in the complexation with heavy metal ions. The oxygen atoms in these functional groups can form coordination bonds, facilitating the coordination interaction with heavy metal ions and promoting the adsorption and fixation of heavy metals.
- (3)
- Ion Exchange: Functional groups in HA possess certain ion exchange capabilities, allowing adsorption through ion exchange with heavy metal ions. This interaction is often influenced by factors such as solution pH and ion concentration.
- (4)
- π electrons: The π electrons of aromatic functional groups play a crucial role in interacting with cations, serving as π electron donors for the adsorption of heavy metals [62]. The cation–π electron interaction is dependent on the aromaticity degree of the HA surface. Higher C/H ratios indicate higher aromaticity, resulting in greater electron donation capacity, reduction capacity, and adsorption capability. Li et al. [63] observed heavy metal adsorption involving cation–π interactions, especially with corn stover biochar.
- (5)
- Precipitation: The interaction between carbonate (CO32−) and sulfate groups (SO42−) in HA and heavy metals is one of the significant behaviors of HA in the environment. These interactions generally occur through mechanisms such as coordination, ion exchange, and adsorption. (1) Coordination: The carboxyl and phenolic functional groups in HAs can form coordination bonds with heavy metals, resulting in the formation of complexes. The carboxyl groups on carbonate and sulfate can provide coordination sites, forming complexes with heavy metal ions, stabilizing their forms of presence, and reducing their toxicity. (2) Ion exchange: The carbonate and sulfate groups in Hs carry negative charges and can participate in ion exchange reactions. In the presence of heavy metal ions in the environment, they can undergo ion exchange with the carbonate and sulfate groups in HAs, being adsorbed onto the surface of HAs, thus reducing the activity and toxicity of heavy metal ions in the environment. (3) Precipitation: Under the influence of high concentrations of carbonate or sulfate, as well as factors such as the concentration of heavy metal ions and pH values, precipitation reactions of heavy metals with carbonate or sulfate may occur. Some heavy metal ions (such as Ca2+, Pb2+) can form carbonate precipitates with carbonate, especially under alkaline conditions. Similarly, some heavy metal ions (such as Cd2+, Pb2+, Hg2+) can also form sulfate precipitates with sulfate, particularly under acidic conditions.
3. Selective Adsorption of Lead Ion by Coexisting System of Multiple Metals
3.1. Types and Physicochemical Characteristics of Heavy Metals in Aqueous Solution
3.2. Application of Selective Adsorbents in Lead-Containing Wastewater
3.2.1. Electrostatic Interaction
3.2.2. Specific Chelation Interaction
3.2.3. Ion Exchange
3.2.4. Pore Structure and Matching with Heavy Metal Size
3.2.5. The pH Values
3.2.6. Chemical Precipitation
3.3. The Limitations, Challenges, and Future Prospects of Selective Adsorption Mechanisms for Pb2+
3.3.1. Limitations and Challenges of Electrostatic Interactions
3.3.2. Limitations and Challenges of Chelation
3.3.3. Limitations and Challenges of Ion Exchange
3.3.4. Limitations and Challenges of Pore Structure and Heavy Metal Size Matching
3.3.5. Limitations and Challenges of pH Values
3.3.6. Limitations and Challenges of Chemical Precipitation
4. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Ions | Radius (Å) | Hydration Radius (Å) | Hydration Energy (kJ mol−1) | Diffusion Coefficient (10−9 m2 s−1) | Stokes Radius (nm) |
---|---|---|---|---|---|
K+ | 1.33 | 3.31 | −295 | 1.957 | 0.124 |
Na+ | 0.95 | 3.58 | −365 | 1.333 | 0.183 |
Ca2+ | 0.99 | 4.12 | −1505 | 0.718 | 0.307 |
Mg2+ | 0.65 | 4.28 | −1830 | 0.706 | 0.345 |
Functional Groups/Ions | –COOH | –OH | –NH2 | –SH | References |
---|---|---|---|---|---|
Na | + | N/A | N/A | N/A | [101] |
Ca | ++ (low pH) | + (high pH) | + | N/A | [102] |
Mg | ++ | + | N/A | N/A | [103] |
Al | ++ | + | N/A | N/A | [104,105] |
References | Years | Modification Methods | Adsorption Capacity (mg/g) | Conclusions |
---|---|---|---|---|
[111] | 2022 | - | Pb2+: 23.11 Cd2+: 12.00 | HA has an affinity for Pb2+ |
[112] | 2021 | Magnetic HA nanoparticles | Pb2+: 105.60 Cu2+: 67.43 Cd2+: 65.23 | HA exhibits selectivity for Pb2+ |
[113] | 2021 | Calcium-modified Fe3O4 nanoparticles encapsulated in HA | Pb2+: 208.33 Cu2+: 98.33 Cd2+: 99.01 | Ca-ion exchange is the main mechanism for the selective adsorption of Pb2+ |
[106] | 2023 | Calcium-doped magnetic HA nano particles | Pb2+: 278.65 Cu2+: 154.31 Cd2+: 145.55 | Ca activates the functional groups of HA |
[114] | 2023 | - | Pb2+: 67.67 | Carboxylic acid is the key functional group affecting the selective adsorption of HA |
[115] | 2012 | Fe3O4 | Pb2+: 29.00 Cd2+: 18.60 | - |
[116] | 2010 | Resin microspheres | Pb2+: 99.19 Cu2+: 45.80 Cd2+: 13.75 | - |
[117] | 2019 | Hydroxypropyl-cyclodextrin-graphene | Pb2+: 99.19 Cu2+: 45.80 | - |
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Xue, S.; Hu, Y.; Wan, K.; Miao, Z. Exploring Humic Acid as an Efficient and Selective Adsorbent for Lead Removal in Multi-Metal Coexistence Systems: A Review. Separations 2024, 11, 80. https://doi.org/10.3390/separations11030080
Xue S, Hu Y, Wan K, Miao Z. Exploring Humic Acid as an Efficient and Selective Adsorbent for Lead Removal in Multi-Metal Coexistence Systems: A Review. Separations. 2024; 11(3):80. https://doi.org/10.3390/separations11030080
Chicago/Turabian StyleXue, Shuwen, Yunhu Hu, Keji Wan, and Zhenyong Miao. 2024. "Exploring Humic Acid as an Efficient and Selective Adsorbent for Lead Removal in Multi-Metal Coexistence Systems: A Review" Separations 11, no. 3: 80. https://doi.org/10.3390/separations11030080
APA StyleXue, S., Hu, Y., Wan, K., & Miao, Z. (2024). Exploring Humic Acid as an Efficient and Selective Adsorbent for Lead Removal in Multi-Metal Coexistence Systems: A Review. Separations, 11(3), 80. https://doi.org/10.3390/separations11030080