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Insight into the selective separation of CO2 from biomass pyrolysis gas over metal-incorporated nitrogen-doped carbon materials: a first-principles study
Li Zhao, Xinru Liu, Zihao Ye, Bin Hu, Haoyu Wang, Ji Liu, Bing Zhang, Qiang Lu
PDF(11622 KB)
PDF(11622 KB)
Insight into the selective separation of CO2 from biomass pyrolysis gas over metal-incorporated nitrogen-doped carbon materials: a first-principles study
The composition of biomass pyrolysis gas is complex, and the selective separation of its components is crucial for its further utilization. Metal-incorporated nitrogen-doped materials exhibit enormous potential, whereas the relevant adsorption mechanism is still unclear. Herein, 16 metal-incorporated nitrogen-doped carbon materials were designed based on the density functional theory calculation, and the adsorption mechanism of pyrolysis gas components H2, CO, CO2, CH4, and C2H6 was explored. The results indicate that metal-incorporated nitrogen-doped carbon materials generally have better adsorption effects on CO and CO2 than on H2, CH4, and C2H6. Transition metal Mo- and alkaline earth metal Mg- and Ca-incorporated nitrogen-doped carbon materials show the potential to separate CO and CO2. The mixed adsorption results of CO2 and CO further indicate that when the CO2 ratio is significantly higher than that of CO, the saturated adsorption of CO2 will precede that of CO. Overall, the three metal-incorporated nitrogen-doped carbon materials can selectively separate CO2, and the alkaline earth metal Mg-incorporated nitrogen-doped carbon material has the best performance. This study provides theoretical guidance for the design of carbon capture materials and lays the foundation for the efficient utilization of biomass pyrolysis gas.
CO2 capture / biomass pyrolysis gas / selective adsorption / carbon materials / first-principles
| [1] |
Hu B , Zhang Z , Xie W , Liu J , Li Y , Zhang W , Fu H , Lu Q . Advances on the fast pyrolysis of biomass for the selective preparation of phenolic compounds. Fuel Processing Technology, 2022, 237: 107465
CrossRef
Google scholar
|
| [2] |
Bruckman V J , Pumpanen J . Biochar use in global forests: opportunities and challenges. Developments in Soil Science, 2019, 36: 427–453
CrossRef
Google scholar
|
| [3] |
Heidari M , Dutta A , Acharya B , Mahmud S . A review of the current knowledge and challenges of hydrothermal carbonization for biomass conversion. Journal of the Energy Institute, 2019, 92(6): 1779–1799
CrossRef
Google scholar
|
| [4] |
Vuppaladadiyam A K , Varsha Vuppaladadiyam S S , Sikarwar V S , Ahmad E , Pant K K , S M , Pandey A , Bhattacharya S , Sarmah A , Leu S Y .
CrossRef
Google scholar
|
| [5] |
Montazersadgh F , Zhang H , Alkayal A , Buckley B , Kolosz B W , Xu B , Xuan J . Electrolytic cell engineering and device optimization for electrosynthesis of e-biofuels via co-valorisation of bio-feedstocks and captured CO2. Frontiers of Chemical Science and Engineering, 2021, 15(1): 208–219
CrossRef
Google scholar
|
| [6] |
Wan S , Wang Y . A review on ex situ catalytic fast pyrolysis of biomass. Frontiers of Chemical Science and Engineering, 2014, 8(3): 280–294
CrossRef
Google scholar
|
| [7] |
Nobarzad M J , Tahmasebpoor M , Heidari M , Pevida C . Theoretical and experimental study on the fluidity performance of hard-to-fluidize carbon nanotubes-based CO2 capture sorbents. Frontiers of Chemical Science and Engineering, 2022, 16(10): 1460–1475
CrossRef
Google scholar
|
| [8] |
Qie Z , Wang L , Sun F , Xiang H , Wang H , Gao J , Zhao G , Fan X . Tuning porosity of coal-derived activated carbons for CO2 adsorption. Frontiers of Chemical Science and Engineering, 2022, 16(9): 1345–1354
CrossRef
Google scholar
|
| [9] |
Mehrvarz E , Ghoreyshi A A , Jahanshahi M . Surface modification of broom sorghum-based activated carbon via functionalization with triethylenetetramine and urea for CO2 capture enhancement. Frontiers of Chemical Science and Engineering, 2017, 11(2): 252–265
CrossRef
Google scholar
|
| [10] |
Bai J , Huang J , Yu Q , Demir M , Akgul E , Altay B N , Hu X , Wang L . Fabrication of coconut shell-derived porous carbons for CO2 adsorption application. Frontiers of Chemical Science and Engineering, 2023, 17(8): 1122–1130
CrossRef
Google scholar
|
| [11] |
Wu D , Liu J , Yang Y , Zheng Y . Nitrogen/oxygen Co-doped porous carbon derived from biomass for low-pressure CO2 capture. Industrial & Engineering Chemistry Research, 2020, 59(31): 14055–14063
CrossRef
Google scholar
|
| [12] |
Hamyali H , Nosratinia F , Rashidi A , Ardjmand M . Anthracite coal-derived activated carbon as an effectiveness adsorbent for superior gas adsorption and CO2/N2 and CO2/CH4 selectivity: experimental and DFT study. Journal of Environmental Chemical Engineering, 2022, 10(1): 107007
CrossRef
Google scholar
|
| [13] |
Mackie I D , DiLabio G A . CO2 adsorption by nitrogen-doped carbon nanotubes predicted by density-functional theory with dispersion-correcting potentials. Physical Chemistry Chemical Physics, 2011, 13(7): 2780–2787
CrossRef
Google scholar
|
| [14] |
Zhang J , Huang D , Shao J , Zhang X , Yang H , Zhang S , Chen H . Activation-free synthesis of nitrogen-doped biochar for enhanced adsorption of CO2. Journal of Cleaner Production, 2022, 355: 131642
CrossRef
Google scholar
|
| [15] |
Tehrani N H M H , Alivand M S , Maklavany D M , Rashidi A , Samipoorgiri M , Seif A , Yousefian Z . Novel asphaltene-derived nanoporous carbon with N-S-rich micro-mesoporous structure for superior gas adsorption: experimental and DFT study. Chemical Engineering Journal, 2019, 358: 1126–1138
CrossRef
Google scholar
|
| [16] |
Choudhuri I , Patra N , Mahata A , Ahuja R , Pathak B . B–N@graphene: highly sensitive and selective gas sensor. Journal of Physical Chemistry C, 2015, 119(44): 24827–24836
CrossRef
Google scholar
|
| [17] |
Li X , Xue Q , He D , Zhu L , Du Y , Xing W , Zhang T . Sulfur–nitrogen codoped graphite slit-pore for enhancing selective carbon dioxide adsorption: insights from molecular simulations. ACS Sustainable Chemistry & Engineering, 2017, 5(10): 8815–8823
CrossRef
Google scholar
|
| [18] |
Abe M , Kawashima K , Kozawa K , Sakai H , Kaneko K . Amination of activated carbon and adsorption characteristics of its aminated surface. Langmuir, 2000, 16(11): 5059–5063
CrossRef
Google scholar
|
| [19] |
Hu B , Liu X , Chen H , Liu J , Wu Y , Zhao L , Zhang B , Lu Q . The selective adsorption mechanism of CO2 from biomass pyrolysis gas on N-doped carbon materials with an electric field: a first-principles study. Journal of the Energy Institute, 2023, 109: 101301
|
| [20] |
Wang Y , Hu X , Guo T , Hao J , Si C , Guo Q . Efficient CO2 adsorption and mechanism on nitrogen-doped porous carbons. Frontiers of Chemical Science and Engineering, 2021, 15(3): 493–504
CrossRef
Google scholar
|
| [21] |
Lin Y C , Teng P Y , Yeh C H , Koshino M , Chiu P W , Suenaga K . Structural and chemical dynamics of pyridinic-nitrogen defects in graphene. Nano Letters, 2015, 15(11): 7408–7413
CrossRef
Google scholar
|
| [22] |
Li Q , Li X , Zhang G , Jiang J . Cooperative spin transition of monodispersed FeN3 sites within graphene induced by CO adsorption. Journal of the American Chemical Society, 2018, 140(45): 15149–15152
CrossRef
Google scholar
|
| [23] |
Montejo-Alvaro F , Martinez-Espinosa J A , Rojas-Chavez H , Navarro-Ibarra D C , Cruz-Martinez H , Medina D I . CO2 adsorption over 3d transition-metal nanoclusters supported on pyridinic N3-doped graphene: a DFT investigation. Materials, 2022, 15(17): 6136
CrossRef
Google scholar
|
| [24] |
Poldorn P , Wongnongwa Y , Mudchimo T , Jungsuttiwong S . Theoretical insights into catalytic CO2 hydrogenation over single-atom (Fe or Ni) incorporated nitrogen-doped graphene. Journal of CO2 Utilization, 2021, 48: 101532
|
| [25] |
Zhao C , Wu H . A first-principles study on the interaction of biogas with noble metal (Rh, Pt, Pd) decorated nitrogen doped graphene as a gas sensor: a DFT study. Applied Surface Science, 2018, 435: 1199–1212
CrossRef
Google scholar
|
| [26] |
Xie T , Wang P , Tian C , Zhao G , Jia J , He C , Zhao C , Wu H . The investigation of adsorption behavior of gas molecules on FeN3-doped graphene. Journal of Sensors, 2022, 2022: 1–8
CrossRef
Google scholar
|
| [27] |
Lou Z , Li W , Yuan H , Hou Y , Yang H , Wang H . Structural rule of N-coordinated single-atom catalysts for electrochemical CO2 reduction. Journal of Materials Chemistry A, 2022, 10(7): 3585–3594
CrossRef
Google scholar
|
| [28] |
Kresse G , Furthmüller J . Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set. Physical Review B: Condensed Matter, 1996, 54(16): 11169–11186
CrossRef
Google scholar
|
| [29] |
Perdew J P , Burke K , Ernzerhof M . Generalized gradient approximation made simple. Physical Review Letters, 1996, 77(18): 3865–3868
CrossRef
Google scholar
|
| [30] |
Kresse G , Joubert D . From ultrasoft pseudopotentials to the projector augmented-wave method. Physical Review B: Condensed Matter, 1999, 59(3): 1758–1775
CrossRef
Google scholar
|
| [31] |
Aledealat K , Aladerah B , Obeidat A . Magnetic properties of transition-metal atomic monolayer in nickel supercell: density functional theory and monte carlo simulation. Journal of Magnetism and Magnetic Materials, 2022, 564: 170173
CrossRef
Google scholar
|
| [32] |
Gong L , Zhang D , Lin C , Zhu Y , Shen Y , Zhang J , Han X , Zhang L , Xia Z . Catalytic mechanisms and design principles for single-atom catalysts in highly efficient CO2 conversion. Advanced Energy Materials, 2019, 9(44): 1902625
CrossRef
Google scholar
|
| [33] |
Lin C , Zhang L , Zhao Z , Xia Z . Design principles for covalent organic frameworks as efficient electrocatalysts in clean energy conversion and green oxidizer production. Advanced Materials, 2017, 29(17): 1606635
CrossRef
Google scholar
|
| [34] |
Solovyev I V , Dederichs P H , Anisimov V I . Corrected atomic limit in the local-density approximation and the electronic structure of d impurities in Rb. Physical Review B: Condensed Matter, 1994, 50(23): 16861–16871
CrossRef
Google scholar
|
| [35] |
NørskovJ KStudtFAbild-PedersenFBligaardT. Fundamental Concepts in Heterogeneous Catalysis, 1st ed. Hoboken: John Wiley & Sons, 2014, 119–122
|
| [36] |
Pham T L M , Nachimuthu S , Kuo J L , Jiang J C . A DFT study of ethane activation on IrO2(110) surface by precursor-mediated mechanism. Applied Catalysis A, General, 2017, 541: 8–14
CrossRef
Google scholar
|
| [37] |
Richards A P , Haycock D , Frandsen J , Fletcher T H . A review of coal heating value correlations with application to coal char, tar, and other fuels. Fuel, 2021, 283: 118942
CrossRef
Google scholar
|
| [38] |
Lopez G , Alvarez J , Amutio M , Mkhize N M , Danon B , van der Gryp P , Görgens J F , Bilbao J , Olazar M . Waste truck-tyre processing by flash pyrolysis in a conical spouted bed reactor. Energy Conversion and Management, 2017, 142: 523–532
CrossRef
Google scholar
|
| [39] |
Li S , Xu S , Liu S , Yang C , Lu Q . Fast pyrolysis of biomass in free-fall reactor for hydrogen-rich gas. Fuel Processing Technology, 2004, 85(8–10): 1201–1211
CrossRef
Google scholar
|
| [40] |
Shi X , Wang J . A comparative investigation into the formation behaviors of char, liquids and gases during pyrolysis of pinewood and lignocellulosic components. Bioresource Technology, 2014, 170: 262–269
CrossRef
Google scholar
|
| [41] |
Wang H , Wang X , Cui Y , Xue Z , Ba Y . Slow pyrolysis polygeneration of bamboo (Phyllostachys pubescens): product yield prediction and biochar formation mechanism. Bioresource Technology, 2018, 263: 444–449
CrossRef
Google scholar
|
/
| 〈 |
|
〉 |
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