School of Civil and Environmental Engineering, Georgia Institute of Technology, Atlanta, Georgia 30332, United States.
Interdisciplinary Program in Climate Studies, Indian Institute of Technology Bombay, Mumbai 400076, India.
Environ Sci Technol. 2022 Jul 5;56(13):9773-9783. doi: 10.1021/acs.est.1c05897. Epub 2022 Jun 15.
India is home to 1.3 billion people who are exposed to some of the highest levels of ambient air pollution in the world. In addition, India is one of the fastest-growing carbon-emitting countries. Here, we assess how two strategies to reuse waste-heat from coal-fired power plants and other large sources would impact PM-air quality, human health, and CO emissions in 2015 and a future year, 2050, using varying levels of policy adoption (current regulations, proposed single-sector policies, and ambitious single-sector strategies). We find that power plant and industrial waste-heat reuse as input to district heating systems (DHSs), a novel, multisector strategy to reduce local biomass burning for heating emissions, can offset 71.3-85.2% of residential heating demand in communities near a power plant (9.3-12.4% of the nationwide heating demand) with the highest benefits observed during winter months in areas with collocated industrial activity and higher residential heating demands (e.g., New Delhi). Utilizing waste-heat to generate electricity via organic Rankine cycles (ORCs) can generate an additional 22 (11% of total coal-fired generating capacity), 41 (8%), 32 (13%), and 6 (5%) GW of electricity capacity in the 2015, 2050-current regulations, 2050-single-sector, and 2050-ambitious-single-sector scenarios, respectively. Emission estimates utilizing these strategies were input to the GEOS-Chem model, and population-weighted, simulated PM showed small improvements in the DHS (0.2-0.4%) and ORC (0.3-3.4%) scenarios, where the minimal DHS PM-benefit is attributed to the small contribution of biomass burning for heating to nationwide PM emissions (much of the biomass burning activity is for cooking). The PM reductions lead to ∼130-36,000 mortalities per year avoided among the scenarios, with the largest health benefits observed in the ORC scenarios. Nationwide CO emissions reduced <0.04% by DHSs but showed larger reductions using ORCs (1.9-7.4%). Coal fly-ash as material exchange in cement and brick production was assessed, and capacity exists to completely reutilize unused fly-ash toward cement and brick production in each of the scenarios.
印度拥有 13 亿人口,这些人生活在世界上一些空气污染最严重的地区。此外,印度也是增长最快的碳排放国家之一。在这里,我们评估了两种策略,即重新利用燃煤电厂和其他大型能源产生的废热,以及在不同政策采纳水平下(当前法规、拟议的单部门政策和雄心勃勃的单部门战略),这两种策略将如何影响 2015 年和未来一年 2050 年的 PM 空气质量、人类健康和 CO 排放。我们发现,将电厂和工业废热作为区域供热系统(DHS)的输入,这是一种新颖的多部门策略,可以减少为取暖而燃烧生物质的排放量,这样可以满足电厂附近社区 71.3-85.2%的住宅取暖需求(占全国取暖需求的 9.3-12.4%),在有工业活动和较高住宅取暖需求的地区(如新德里),冬季的效益最为显著。利用有机朗肯循环(ORC)将废热转化为电能,可以在 2015 年、2050 年现行法规、2050 年单部门和 2050 年雄心勃勃的单部门情景下,分别额外产生 22(占总燃煤发电能力的 11%)、41(8%)、32(13%)和 6(5%)GW 的发电能力。这些策略的排放估算被输入到 GEOS-Chem 模型中,人口加权后的模拟 PM 显示 DHS(0.2-0.4%)和 ORC(0.3-3.4%)情景有所改善,其中 DHS 的 PM 效益最小,这归因于生物质燃烧对取暖的贡献很小,对全国 PM 排放的贡献也很小(大部分生物质燃烧活动是用于烹饪)。PM 减少导致每年避免了 130-36000 人死亡,在 ORC 情景中观察到的健康效益最大。DHS 导致全国 CO 排放量减少<0.04%,而 ORC 则导致排放量大幅减少(1.9-7.4%)。还评估了将粉煤灰作为水泥和砖生产中的材料交换,在每种情景下,都有能力将未使用的粉煤灰完全重新用于水泥和砖的生产。
