Modular, Chemical-Free Advanced Oxidation of 1,4-Dioxane and its Co-Contaminants in Ground Water

地下水中 1,4-二恶烷及其共污染物的模块化、无化学品高级氧化

基本信息

批准号：
10361889
负责人：
Jaehong Kim
金额：
$ 22.99万
依托单位：
YALE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2022
资助国家：
美国
起止时间：
2022-09-07 至 2027-06-30
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10361889
关键词：
Acoustics Adsorption Air Anthraquinones Benchmarking Benign Carbon Dioxide Cells Characteristics Charge Chemicals Chemistry Collaborations Consumption Coupled Coupling Decentralization Dioxanes Distributed Systems Dose Electricity Electron Transport Engineering Environmental sludge Esthetics Ethylene Dichlorides Evolution Excision Exhibits Exposure to Filtration Gases Goals Health Household Human Hydrogen Hydrogen Peroxide Immobilization Industry Iron Lead Light Manganese Mediating Membrane Metals Methods Municipalities Oxidants Oxygen Parents Performance Phase Physiologic pulse Precipitation Privatization Process Production Reaction Reactive Oxygen Species Research Project Grants Risk Scheme Site Source Structure Superfund Surface System Technology Technology Transfer Testing Time Toxic effect Toxicology Trichloroethanes Trichloroethylene Ultraviolet Rays Water Water Pollutants base catalyst chemical addition chemical property cost design drinking water experimental study exposed human population field study ground water hydrophilicity improved innovation interfacial nanobubble nanoscale next generation novel operation oxidation performance tests physical property pollutant prototype remediation residence sensor technology validation ultraviolet ultraviolet irradiation water treatment

项目摘要

ABSTRACT The ultimate goal of this remediation project is to design, fabricate, test, and implement point-of-use, small- scale, water treatment systems that can remove 1,4-dioxane (1,4-DX) and its frequently co-occurring contaminants, trichloroethylene (TCE), 1,1-dichloroethane (1,1-DCA) and 1,1,1,-trichloroethane (1,1,1-TCA), from contaminated ground water. The advanced oxidation process (AOP)–the process that employs highly reactive •OH as main oxidant–is considered to be the most effective among established water treatment methods for the destruction of these contaminants. However, enabling AOP in a small-scale, distributed system (i.e., in contrast to centralized large-scale treatment and water delivery through a network of pipe) is technically challenging due to the requirement for a precursor chemical (such as H2O2) that needs to be activated on site to produce •OH and the high energy demand. We will synthesize efficient catalyst materials, engineer various components of the system, and fabricate two highly-innovative prototype AOP reactors. The first reactor will employ a new catalyst that can selectively produce high concentrations of H2O2 using only water and oxygen as a source. The produced H2O2 will be activated by another newly-developed catalyst to produce •OH without any external energy/chemical supplies and without producing undesirable byproducts (which would otherwise require additional treatment). Coupled together, this catalytic system will enable for the first time AOP of ground water in a small, compact, distributed water treatment system. The second reactor will employ nanobubble technology. In this system, ambient air will be introduced to the water in the form of nanobubbles which collapse to produce •OH that will destroy 1,4-DX. Strategies to enhance the production of •OH through promotion of effective bubble collapse will be developed. Unlike any existing AOPs, both reactors will not require continuous supply of chemicals. In addition, they will either be solar powered (completely off-grid) or use a much smaller amount of electricity than conventional AOPs that employ ultraviolet (UV) irradiation. We will test the performance of prototype reactors and compare them with benchmark UV/H2O2 process (i.e., adding H2O2 and irradiating UV light). This will involve a comprehensive analysis of the efficiency of parent compound (1,4-DX) destruction, as well as the evolution of reaction byproducts. Reduction of the deleterious effects of consuming 1,4-DX-containing water will be investigated in collaboration with Research Project 1. The prototype reactors will undergo testing in select field sites in Region 1 (identified as being contaminated by Research Project 2) to determine their efficiency under real world situations and their activity under long term conditions (employing sensors developed by Research Project 3). By promoting the continual removal of 1,4-DX and its co-occurring contaminants from drinking water sources, this project will directly reduce human exposure to these pollutants and thereby limit their adverse health effects.

抽象的该修复项目的最终目标是设计、制造、测试和实施使用点、小型水垢、可去除 1,4-二恶烷 (1,4-DX) 及其常见共存物的水处理系统污染物，三氯乙烯 (TCE)、1,1-二氯乙烷 (1,1-DCA) 和 1,1,1,-三氯乙烷 (1,1,1-TCA)，来自受污染地下水的高级氧化工艺（AOP）——该工艺采用高度氧化工艺。反应性•OH作为主要氧化剂——被认为是现有水处理中最有效的然而，AOP 能够以小规模、分布式的方式被破坏。系统（即，与通过管道网络进行集中大规模处理和供水相比）由于需要前体化学品（例如 H2O2），因此在技术上具有挑战性现场激活以产生·OH 和高能量需求。我们将合成高效的催化剂材料，设计系统的各种组件，并制造两个高度创新的原型 AOP 反应器，第一个反应器将采用一种新型催化剂。仅使用水和氧气作为来源选择性地产生高浓度的 H2O2。将被另一种新开发的催化剂激活，无需任何外部能源/化学物质即可产生·OH 供应且不会产生不需要的副产品（否则需要额外的处理）。结合在一起，该催化系统将首次在小型、紧凑、分布式水处理系统。第二个反应器将采用纳米气泡技术。环境空气将以纳米气泡的形式引入水中，纳米气泡破裂后产生 OH，破坏1,4-DX 通过促进有效的气泡破裂来增加•OH 的产生。与任何现有的 AOP 不同，这两个反应堆不需要持续供应化学品。此外，它们要么采用太阳能供电（完全离网），要么使用比采用紫外线 (UV) 照射的传统 AOP。我们将测试原型反应器的性能并将其与基准 UV/H2O2 进行比较过程（即添加 H2O2 和照射紫外光）这将涉及效率的综合分析。母体化合物 (1,4-DX) 的破坏，以及反应副产物的减少。将与研究机构合作调查饮用含有 1,4-DX 的水的有害影响项目 1. 原型反应堆将在 1 区（确定为受研究项目 2) 污染，以确定其在现实世界情况下的效率及其活动在长期条件下（采用研究项目 3 开发的传感器）。去除饮用水源中的 1,4-DX 及其共生污染物，该项目将直接减少人类接触这些污染物，从而限制其对健康的不利影响。