@article{scholars14552,
           pages = {1554--1561},
         journal = {Water Environment Research},
          volume = {93},
            note = {cited By 5},
       publisher = {John Wiley and Sons Inc},
          number = {9},
           title = {Hazardous wastewater treatment by low-cost sorbent with in situ regeneration using hybrid solar energy-electrochemical system},
            year = {2021},
             doi = {10.1002/wer.1537},
        abstract = {Hazardous industrial wastes negatively impact the environment by creating issues for aquatic as well as human's life. This study investigates the treatment of hazardous industrial wastewater using cost-effective graphite adsorbent along with electrochemical regeneration integrated with renewable solar energy. The synthetic industrial effluent containing crystal violet dye was treated using an adsorbent (Nyex{\^a}?c 1000) having a surface area of 1.0{\^A} m2{\^A} g{\^a}??1. The efficiency of removing solute was found to be more than 90. The adsorbent regeneration efficiency was achieved at 99.5 by passing a charge of 100{\^A} C{\^A} g{\^a}??1 at current density of 10{\^A} mA{\^A} cm{\^a}??2 for 1{\^A} h. Solar energy was integrated with electrochemical reactor for the regeneration of adsorbent to make the system cost-effective and self-sustainable. Practitioner points: Industrial hazardous wastewater treatment with a cost-effective graphite integrated adsorbent. Development of renewable solar energy-integrated with electrochemical system for regeneration. Regeneration efficiency of adsorbent Nyex{\^a}?c 1000 was achieved around 99.5 with integrated system. Sustainable system was introduced to incorporate with renewable energy for waste water treatment. {\^A}{\copyright} 2021 Water Environment Federation},
            issn = {10614303},
          author = {Khan, M. M. and Asghar, H. M. A. and Saulat, H. and Chawla, M. and Rafiq, S. and Khan, M. M. and Ya Jie, W. and Aslam, M. and Mukhtar, A.},
             url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85102531998&doi=10.1002\%2fwer.1537&partnerID=40&md5=69f981f405271a2721df12fc06e5412e},
        keywords = {Cost effectiveness; Costs; Effluents; Graphite; Hazards; Industrial wastes; Industrial water treatment; Sewage; Waste treatment; Wastewater treatment, Adsorbent regeneration; Electrochemical reactor; Electrochemical regeneration; Electrochemical systems; Hazardous industrial wastes; Hazardous wastewaters; Industrial wastewaters; Regeneration efficiency, Solar energy, carbimazole; crystal violet; graphite; industrial effluent; sorbent; graphite, alternative energy; effluent; graphite; industrial waste; regeneration; surface area; wastewater; wastewater treatment, Article; controlled study; human; waste water management; solar energy; wastewater; water management, Graphite; Humans; Solar Energy; Waste Water; Water Purification}
}