# Mechanistic Insights into NDMA Adsorption onto Selected Pollutants and Their Removal via Direct Rapid Sand Filtration and After Enhanced Coagulation

**Authors:** Olubunmi M. Olukowi, Tian Tian, Xie Yan, Yuejun Zhang

PMC · DOI: 10.3390/molecules30102094 · 2025-05-08

## TL;DR

This study explores how pollutants and coagulation improve the removal of the carcinogen NDMA through sand filtration.

## Contribution

The study provides mechanistic insights into NDMA adsorption and removal via rapid sand filtration and enhanced coagulation.

## Key findings

- NDMA removal rates increased with filtrate volume and were enhanced by water pollutants and coagulation.
- NDMA adsorption is influenced by microstructure, polar functional groups, and surface charge interactions.
- Enhanced coagulation improves NDMA removal efficiency in sand filtration systems.

## Abstract

N-nitroso dimethylamine (NDMA), a common nitrogen disinfection by-product and carcinogen, can be removed using rapid sand filtration (RSF) after coagulation; however, its removal mechanism has not been extensively studied. This study analyzed NDMA and the water pollutant parameter removal rate change tendency in the filtrates of simulated supernatants directly and after enhanced coagulation (EC) using composite PAC/PDMDAAC that mimics treated Yangtze River water separated into blank, single-component, and mixed multi-component (MMC) water systems containing NDMA and pollutants like diatomite (DTA), humic acid salt (HAs), dimethyl amine (DMA), and ammonium nitrate (NH4NO3). Meanwhile, a correlation analysis of removal rate changes and adsorption analysis using SEM (surface morphology), polar functional groups, and zeta potentials (surface charge) were performed to obtain mechanistic insights into NDMA removal via adsorption. The results revealed that removal rates gradually increased with an increasing volume of filtrates, and there were correlations for NDMA-HAs, NDMA-DMA, NDMA-DTA, and NDMA-NH4NO3. The highest NDMA removal rates in the blank system were 10.29% using RSF directly and 12.84% after enhanced coagulation, indicating improved efficiency with coagulation. However, single and mixed systems showed that NDMA removal rate changes were enhanced by water pollutants and coagulation functions. The NDMA removal mechanism was verified, and it was revealed that the level of NDMA adsorption on water pollutants varies based on microstructure, available polar functional groups, and surface charge interactions that are strengthened by coagulation functions for improving the affinity of NDMA and pollutants on the sand surface. These findings provide new insights into NDMA removal mechanisms via adsorption and highlight the role of water pollutants and enhanced coagulation in strengthening rapid sand filtration for NDMA removal.

## Linked entities

- **Chemicals:** N-nitroso dimethylamine (PubChem CID 6124), NDMA (PubChem CID 6124), dimethyl amine (PubChem CID 674), ammonium nitrate (PubChem CID 22985)

## Full-text entities

- **Chemicals:** NO (MESH:D009614), DTA (MESH:C042899), diatomite (MESH:C033787), N-nitroso dimethylamine (MESH:D004128), DMA (MESH:C034516), HAs (-), nitrogen (MESH:D009584), water (MESH:D014867), ammonium nitrate (MESH:C006568)

## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12113702/full.md

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Source: https://tomesphere.com/paper/PMC12113702