孙健 - 南京师范大学 - 能源与机械工程学院

个人简介

教育背景 2012.09-2017.06 华中科技大学煤燃烧国家重点实验室热能工程博士研究生； 2008.09-2012.06 华北电力大学能源与机械工程学院热能与动力工程本科；工作经历 2017.06-至今南京师范大学能源与机械工程学院讲师；

研究领域

钙循环耦合太阳能光热发电站（CaL-CSP）热化学储能、生物质制氢、粉体吸收剂成型造粒、高钙废弃物资源化利用

近期论文

查看导师最新文章（温馨提示：请注意重名现象，建议点开原文通过作者单位确认）

[25] Sun J, Guo Y, Yang Y, Li W, Zhou Y, Zhang J, et al. Mode investigation of CO2 sorption enhancement for titanium dioxide-decorated CaO-based pellets. Fuel 2019;256:116009. [24] Sun J, Sun Y, Yang Y, Tong X, Liu W. Plastic/rubber waste-templated carbide slag pellets for regenerable CO2 capture at elevated temperature. Applied Energy 2019;242:919-30. [23] Sun J, Liang C, Tong X, Guo Y, Li W, Zhao C, et al. Evaluation of high-temperature CO2 capture performance of cellulose-templated CaO-based pellets. Fuel 2019;239:1046-54. （ESI高被引及热点论文） [22] Sun J, Yang Y, Guo Y, Zhao C, Zhang J, Liu W, et al. Stabilized performance of Al‐decorated and Al/Mg co-decorated, spray-dried CaO-based CO2 sorbents. Chemical Engineering & Technology 2019;42(6):1283-92. [21] Sun J, Yang Y, Liu W. Evaluating redox reactivity of CuO-based oxygen carriers synthesized with organometallic precursors. Journal of Thermal Analysis and Calorimetry 2019, https://doi.org/10.1007/s10973-019-08492-2. [20] Hu Y, Guo Y, Sun J, Li H, Liu W. Progress in MgO sorbents for cyclic CO2 capture: A comprehensive review. Journal of Materials Chemistry A 2019;7:20103-20120. [19] Wang P, Sun J, Guo Y, Zhao C, Li W, Wang G, et al. Structurally improved, urea-templated, K2CO3-based sorbent pellets for CO2 capture. Chemical Engineering Journal 2019;374:20-8. [18] Yang Y, Liu W, Hu Y, Sun J, Tong X, Li Q, et al. Novel low cost Li4SiO4-based sorbent with naturally occurring wollastonite as Si-source for cyclic CO2 capture. Chemical Engineering Journal 2019;374:328-37. [17] Tong X, Liu W, Yang Y, Sun J, Hu Y, Chen H, et al. A semi-industrial preparation procedure of CaO-based pellets with high CO2 uptake performance. Fuel Process Technology 2019;193:149-58. [16] Wang W, Liu W, Sun J, Hu Y, Yang Y, Wen C. Reactivation of CaO-based sorbents via multi-acidification under N2 or oxy-fuel (with and without SO2) calcination conditions. Fuel 2019;244:13-21. [15] Zhao C, Guo Y, Yan J, Sun J, Li W, Lu P. Enhanced CO2 sorption capacity of amine-tethered fly ash residues derived from co-firing of coal and biomass blends. Applied Energy 2019;242:453-61. [14] Guo Y, Tan C, Wang P, Sun J, Li W, Zhao C, et al. Magnesium-based basic mixtures derived from earth-abundant natural minerals for CO2 capture in simulated flue gas. Fuel 2019;243:298-305. >>>2018: [13] Sun J., Yang Y., Guo Y., Xu Y., Li W., Zhao C., et al. Stabilized CO2 capture performance of wet mechanically activated dolomite. Fuel 2018; 222:334-342. [12] Sun J., Liu W., Hu Y, Yang Y., Xu Y., Xu M., Acidification optimization and granulation of steel slag-derived sorbent for CO2 capture. Chemical Engineering & Technology 2018; 41(10):2077-86. [11] Yang Y, Liu W, Hu Y, Sun J, Tong X, Chen Q, et al. One-step synthesis of porous Li4SiO4-based adsorbent pellets via graphite moulding method for cyclic CO2 capture. Chemical Engineering Journal 2018;353:92-9. [10] Xu Y, Ding H, Luo C, Zheng Y, Zhang Q, Li X, et al. Potential Synergy of Chlorine and Potassium, Sodium Elements in Carbonation Enhancement of CaO-Based Sorbents. ACS Sustainable Chemistry & Engineering 2018;6(9):11677-84. [9] Guo Y, Zhao C, Sun J, Li W, Lu P. Facile synthesis of silica aerogel supported K2CO3 sorbents with enhanced CO2 capture capacity for ultra-dilute flue gas treatment. Fuel 2018;215:735-43. [8] Yang Y, Liu W, Hu Y, Sun J, Chen Q, Tong X, et al. Enhancement of CO2 absorption in Li4SiO4 by acidification and eutectic doping. Energy&Fuels 2018;32(12):12758-65.