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An insight into microelectronics industry wastewater treatment, current challenges, and future perspectives: a critical review
The microelectronics industry wastewater is attracting the scientific community and industry attention due to the high amount of organic and inorganic pollutants produced. Pollutants in microelectronic wastewater are considered qualitative contaminants, found in low concentrations but present with h...
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| Published in: | Applied water science 2024-04, Vol.14 (4), p.64-17, Article 64 |
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| cites | cdi_FETCH-LOGICAL-c468t-ec3ece5a5a7ef35f41dea01eccdc3a4c1a180d19c3399e7b036f53363a36e5983 |
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| container_title | Applied water science |
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| creator | Noman, Efaq Ali Ali Al-Gheethi, Adel Al-Sahari, Mohammed Yashni, G. Mohamed, Radin Maya Saphira Radin Soon, Chin Fhong Nguyen, Hong-Ha T. Vo, Dai-Viet N. |
| description | The microelectronics industry wastewater is attracting the scientific community and industry attention due to the high amount of organic and inorganic pollutants produced. Pollutants in microelectronic wastewater are considered qualitative contaminants, found in low concentrations but present with high risks to the environment and public health. The current paper highlights the most common pollutants in microelectronics wastewater and discusses the recent treatment technologies used to remove these contaminates. The review process was conducted based on the identification and screening of microelectronic wastewater and the principle of contaminant detection reported in previous research literature. It appears that tetramethylammonium hydroxide and ammonium are the major organic compounds in microelectronic wastewater, while heavy metals are among the inorganic pollutants with high environmental toxicity. The membrane filtration is the most efficient method for removing the pollutants (more than 90%) and producing ultrapure water. However, wastewater should be subjected to primary treatment using chemical and biological methods before undergoing the ultrafiltration process. The zero-discharge concept is more applicable in the microelectronics industries due to the stringent regulations associated with these industries. Microelectronic sludge represents the main challenge in wastewater recycling, while advanced treatment methods have been suggested for sludge treatment. More effort is required to recycle microelectronics owing to the high prices related to the disposal of these solids’ wastes. |
| doi_str_mv | 10.1007/s13201-024-02104-7 |
| format | article |
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Pollutants in microelectronic wastewater are considered qualitative contaminants, found in low concentrations but present with high risks to the environment and public health. The current paper highlights the most common pollutants in microelectronics wastewater and discusses the recent treatment technologies used to remove these contaminates. The review process was conducted based on the identification and screening of microelectronic wastewater and the principle of contaminant detection reported in previous research literature. It appears that tetramethylammonium hydroxide and ammonium are the major organic compounds in microelectronic wastewater, while heavy metals are among the inorganic pollutants with high environmental toxicity. The membrane filtration is the most efficient method for removing the pollutants (more than 90%) and producing ultrapure water. However, wastewater should be subjected to primary treatment using chemical and biological methods before undergoing the ultrafiltration process. The zero-discharge concept is more applicable in the microelectronics industries due to the stringent regulations associated with these industries. Microelectronic sludge represents the main challenge in wastewater recycling, while advanced treatment methods have been suggested for sludge treatment. 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| subjects | Ammonium Ammonium compounds Aquatic Pollution Comparative Law Contaminants Earth and Environmental Science Earth Sciences Environmental risk Heavy metals Hydrogeology Hydroxides Industrial and Production Engineering Industry International & Foreign Law Low concentrations Membrane filtration Metals Microelectronics Nanotechnology Organic compounds Pollutant removal Pollutants Private International Law Public health Recovery Recycling Review Article Semiconductor wastewater Sludge Sludge treatment Tetramethyl ammonium hydroxide Toxicity Treatment technologies Ultrafiltration Waste Water Technology Wastewater treatment Water Industry/Water Technologies Water Management Water Pollution Control |
| title | An insight into microelectronics industry wastewater treatment, current challenges, and future perspectives: a critical review |
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