目前的研究重点是利用层状双氢氧化物 (LDH) 的吸附特性去除芳烃，因为它生产简单，适合生态，成本低，
易于通过插层有机分子进行修饰，从而导致亲水性变为疏水性有助于提高单芳烃和双芳烃的去除率。在这项工作中，
纳米层结构（ AlZn NLS）通过不同的技术制备和表征，但不能去除芳烃。在有机分子（依次为 4- 氨基苯甲酸、水杨酸、
己二酸和正癸酸）嵌入后，制备了一系列 AlZn 纳米杂化物，并显示出对单芳烃和双芳烃的显着去除。基于正癸酸制
备的纳米杂化物在去除单芳烃 (33.5%) 和双芳烃 (28.6%) 方面显示出显着的效果。目前的研究得出结论，由于纳米层
的层间距扩大和疏水特性的增加， AlZn 的纳米层状结构对于去除芳香族物质变得有效。

双功能纳米杂化物、石油馏分、苯基壬烷、甲基萘

1. A. Hassani, R. Darvishi Cheshmeh Soltani, M. Kıransan, S. Karaca, C. Karaca, A. Khataee, Ultrasound-assisted

adsorption of textile dyes using modified nanoclay: Central

composite design optimization, Korean J. Chem. Eng. 33

(2016) 178–188. 10.1007/s11814-015-0106-y.

2. A. Hassani, A.R. Khataee, Activated carbon fiber for

environmental protection, in: J.Y. Chen (Ed.), Act. Carbon

Fiber Text, Woodhead Publishing, Oxford, 2017, pp. 245–

280.

3. L. Santamaría, A. Gil, M.A. Vicente, S.A. Korili, Hydrotalcite-like compounds and related materials as

catalysts for the photodegradation of pharmaceutical compounds: Synthesis and catalytic performances, in: P. Singh,

A. Borthakur, P. K. Mishra, D. Tiwary (Eds.), Nano-Materials as Photocatal. Degrad. Environ. Pollut., Elsevier, 2020,

pp. 79–90, https://doi.org/ 10.1016/ B978-0-12- 818598-

8.00005-5.

4. Ansaf V. Karim , Aydin Hassani , Paria Eghbali ,

P.V. Nidheesh , Nanostructured modified layered double

hydroxides (LDHs)-based catalysts: A review on synthesis,

characterization, and applications in water remediation by

advanced oxidation processes Current Opinion in Solid State

and Materials Science 26 (2022) 10096.

5. S. Sharma, G. Sharma, A. Kumar, P. Dhiman, T.S.

AlGarni, M. Naushad, Z.A. ALOthman, F.J. Stadler, Controlled synthesis of porous Zn/Fe based layered double

hydroxides: Synthesis mechanism, and ciprofloxacin adsorption, Sep. Purif. Technol. 278 (2022) 119481. 10.1016/j.

seppur.2021.119481.

6. R. Wijitwongwan, S. Intasa-ard, M. Ogawa, Preparation of Layered Double Hydroxides toward Precisely

Designed Hierarchical Organization, ChemEngineering 3

(2019) 68, https://www.mdpi.com/2305-7084/3/3/68. [143]

S. Intasa-Ard, S. Bureekaew, M. Ogawa, Efficient production of MgAl layered double hydroxide nanoparticle, J. Ceram. Soc. Japan. 127 (2019) 11–17, https:// doi.org/10.2109/

jcersj2.18140.

7. N. Chubar, R. Gilmour, V. Gerda, M. Micˇušík, M.

Omastova, K. Heister, et al., Layered double hydroxides as

the next generation inorganic anion exchangers: Synthetic

methods versus applicability, Adv. Colloid Interface Sci. 245

(2017) 62–80.

8. S. Mallakpour, M. Hatami, Condensation polymer/

layered double hydroxide NCs: Preparation, characterization, and utilizations, Eur. Polym. J. 90 (2017) 273–300.

9. G. Starukh, Photocatalytically Enhanced Cationic

Dye Removal with Zn-Al Layered Double Hydroxides, Nanoscale Res. Lett. 12 (2017) 391, https://doi. org/ 10.1186/

s11671-017-2173-y.

10. X. Zhao, C. Niu, L. Zhang, H. Guo, X. Wen, C.

Liang, G. Zeng, Co-Mn layered double hydroxide as an

effective heterogeneous catalyst for degradation of organic

dyes by activation of peroxymonosulfate, Chemosphere 204

(2018) 11–21, 10.1016/ j.chemosphere. 2018.04.023.

11. Recent innovations in functionalized layered double

hydroxides: Fabrication, characterization, and industrial applications Shadpour Mallakpour , Masoud Hatami , Chaudhery Mustansar Hussain Advances in Colloid and Interface

Science 283 (2020) 102216

12. N.A.G. Gómez, G.M. Silva, M. Helena, Wilhelmb

and Fernando Wypych, Zn2Al Layered Double Hydroxides Intercalated with Nitrate and p-Aminobenzoate as

Ultraviolet Protective Agents in Low-Density Polyethylene

Nanocomposites and Natural Insulating Oils, J. Braz. Chem.

Soc. 00 (00) (2019) 1–11. https://doi.org/10.21577/0103-

5053.20190262.