Tài liệu hạn chế xem trước, để xem đầy đủ mời bạn chọn Tải xuống
1
/ 76 trang
THÔNG TIN TÀI LIỆU
Thông tin cơ bản
Định dạng
Số trang
76
Dung lượng
6,53 MB
Nội dung
VIETNAM NATIONAL UNIVERSITY, HANOI VIETNAM JAPAN UNIVERSITY TA THI LUONG QUANTUM SIMULATION OF THE ADSORPTION OF TOXIC GASES ON THE SURFACE OF BOROPHENE MASTER'S THESIS Hanoi, 2019 VIETNAM NATIONAL UNIVERSITY, HANOI VIETNAM JAPAN UNIVERSITY TA THI LUONG QUANTUM SIMULATION OF THE ADSORPTION OF TOXIC GASES ON THE SURFACE OF BOROPHENE MAJOR: NANOTECHNOLOGY CODE: PILOT RESEARCH SUPERVISOR: Dr DINH VAN AN Hanoi, 2019 ACKNOWLEDGMENT First of all, I sincerely appreciate the great help of my supervisor, Dr Dinh Van An Thank you for all your thorough and supportive instructions, your courtesy, and your encouragement This thesis absolutely could not be conducted well without your dedicated concerns Second of all, I would like to show my gratefulness to Prof Morikawa Yoshitada, my supervisor during my internship time at Osaka University Your guidance helps me a lot to get a more profound insight into my research topic as well as researchrelated works Third of all, I want to express my warm thanks to my classmate, Pham Trong Lam Thanks to you, I got acquaintance more easily with computational material science Thank you for your willingness to help; it means a lot to me Last but not least, I also would like to thank Vietnam Japan University and the staff working here for their necessary supports This research is funded by National Foundation for Science and Technology Development (NAFOSTED) under grant number 103.01-2018.315 i CONTENTS Acknowledgment CONTENTS LIST OF TABLES LIST OF FIGURES LIST OF ABBREVIATIONS ABSTRACT Chapter INTRODUCTION 1.1Background of the research 1.2Objectives and subjects of the research 1.2.1Adsorbent material: Borop 1.2.2Gas molecules 1.3Toxic gases adsorption on two-dimensional materials 1.3.1Gas adsorption on other tw 1.3.2Adsorption application of b 1.4Thesis outline Chapter THEORETICAL BASICS AND METHODS 2.1Density Functional Theory 2.2Vasp 2.3Bader charge analysis 2.4Calculation scheme Chapter RESULTS AND DISCUSSION 3.1Adsorbent characteristics 3.2Energetically favorable configurations 3.2.1CO - borophene 3.2.2CO2 - borophene 3.2.3NH3 - borophene 3.2.4NO2 - borophene 3.2.5NO - borophene 3.3Adsorption energy and reaction length 3.3.1Adsorption energy and ad employed functionals 3.3.2Comparison of adsorption 3.4Potential energy surface 3.5Electronic characteristic 3.6Charge transfer characteristic ii 3.6.1 Charge analysis of the (CO – borophene) system 39 3.6.2 Charge analysis of the (CO2 - borophene) system 40 3.6.3 Charge analysis of the (NO - borophene) system 42 3.6.4 Charge analysis of the (NO2 - borophene) system 43 3.6.5 Charge analysis of the (NH3 - borophene) system 44 CONCLUSION 47 FUTURE PLANS 48 REFERENCES 49 iii LIST OF TABLES Page Table 1.1 The adsorption energy of CO, CO2, NO2, NO, and NH3 on different twodimensional materials (eV) Table 3.1 Calculated lattice constants of β12 borophene vs experimental data .20 Table 3.2 Bader charge analysis of the (CO - borophene) system 39 Table 3.3 Bader charge analysis of the (CO2 – borophene) system .41 Table 3.4 Bader charge analysis of the (NO – borophene) system .42 Table 3.5 Bader charge analysis of the (NO2 – borophene) system .43 Table 3.6 Bader charge analysis of the (NH3 – borophene) system .44 iv LIST OF FIGURES Page Figure 1.1 Elements predicted to be precursors of synthetic elemental 2D materials and their synthetic methods Figure 1.2 Borophene assumed to be synthesized on Ag (111) substrate (a) buckled triangular borophene, (b) β12 borophene, and (c) χ3 borophene Figure 2.1 The flow chart of gas absorbing calculations .19 Figure 3.1 The calculated supercell of β12 boron sheet after optimization 20 Figure 3.2 Band structure and DOS of the unit cell of β12 borophene 21 Figure 3.3 Top view and side view of the most stable configurations of CO on borophene 22 Figure 3.4 Top view and side view of the most stable configurations of CO2 on borophene 23 Figure 3.5 Top view and side view of the most stable configurations of NH3 on borophene 23 Figure 3.6 Top view and side view of the most stable configurations of NO2 on borophene 24 Figure 3.7 Top view and side view of the most stable configurations of NO on borophene using different vdW functionals 25 Figure 3.8 Adsorption energy change accordingly to the distance of the (a) CO and (b) CO2 molecule and borophene in comparison 26 Figure 3.9 Adsorption energy change accordingly to the distance of the (a) NH and (b) NO2 molecule and borophene 28 Figure 3.10 Adsorption energy change accordingly to the distance between NO molecule and borophene 29 Figure 3.11 Comparison among gases of the shortest distance between gas molecules and substrate (dz), the distance from the massed center of gas molecules to the substrate (dc), and the adsorption energy (Ea) using optPBE-vdW functional 30 Figure 3.12 Potential energy surface of CO adsorbed borophene 31 Figure 3.13 Potential energy surface of CO2 adsorbed borophene 32 Figure 3.14 The projected binding energy of NH3 along the surface of borophene 33 Figure 3.15 Potential energy surface of borophene-NO 34 Figure 3.16 Potential energy surface of NO2 – borophene 35 Figure 3.17 Band structure and DOS of CO - borophene 36 Figure 3.18 Band structure and DOS of CO2 - borophene 37 v Figure 3.19 Band structure and DOS of NH3 - borophene Figure 3.20 Band structure and DOS of NO - borophene Figure 3.21 Band structure and DOS of NO2 - borophene Figure 3.22 Charge density difference after CO adsorption illustrated using isosurface (isosurface level = 0.00034) Figure 3.23 Charge density difference after CO2 adsorption illustrated using isosurface (isosurface level = 0.00054) Figure 3.24 Charge density difference after NO adsorption (isosurface level = 0.003) Figure 3.25 Charge density difference after NO2 adsorption illustrated using isosurface (isosurface level = 0.01) Figure 3.26 Charge density difference after adsorbing NH3 (isosurface level = 0.0012) Figure 3.27 Charge transfer of CO, CO2, NH3, NO, NO2, and SO2 and borophene 45 vi LIST OF ABBREVIATIONS 2D Two-dimensional DFT Density Functional Theory VASP Vienna Ab initio Software Package vdW van der Waals DOS Density of state KS Kohn-Sham MO Molecular orbital HF Hartree-Fock 3D Three-dimensional PAW Projector Augmented Wave vii ABSTRACT 2D materials have attracted significant research interest due to their excellent characteristics Borophene, a new member of the 2D material family, was proven that it has a unique structure and promising properties by both empirical and theoretical studies In this study, the adsorption configuration, adsorption energy of toxic gas molecules (CO, NO, CO2, NH3, and NO2) on 12 – borophene was investigated by first – principle calculations using three van der Waals correlation functionals: revPBE-vdW, optPBE-vdW, and vdW-DF2 The most stable configurations and diffusion possibilities of the gas molecules on the 12 – borophene surface were determined visually by using Computational DFT-based Nanoscope [10] The nature of bonding and interaction between gas molecules and 12 – borophene are also disclosed by using the density of states analysis and Bader charge analysis The obtained results are not only considerable for understanding gas molecules on borophene but also useful for technological applications of borophene in very near future Keywords: 12 – borophene, DFT, adsorption, toxic gases viii CONCLUSION In this work, the adsorbability of borophene was examined throughout firstprinciples calculation of the energy configuration, the adsorption potential energy, the density of state for five poisonous gases i.e., CO, CO 2, NO, NH3, and NO2 The charge transfer and Bader charge analysis were also given for analyzing the adsorption mechanism Remarkably, CO, CO 2, and NH3 are physically adsorbed on β12 borophene, while NO and NO2 are chemically adsorbed on β12 borophene Regarding charge transferring behaviors, CO, CO and NO2 are electron acceptors, whereas NO and NH3 are electron donators when being absorbed on the surface of borophene In short, borophene expresses as a material with high selectivity, which is much more sensitive to NO and NO2 gases Considerably, although the adsorption energy of NO on borophene is just in weak chemical adsorption range, which is neither too weak nor too strong for borophene as an adsorbent, NO has a great charge transfer with borophene It is very potential characteristic, facilitating favorable conditions for borophene to be an excellent sensing material i.e., to fabricate a sensitive and recyclable sensor 47 FUTURE PLANS There are many rooms to explore in the field of the gas adsorbability of borophene which has huge applications in the future With great potential, β 12 borophene as well as other types of boron nanosheets or nanoribbons are worth to be intensively studied For further works, we want to carry out calculations for gas adsorption on borophene with other research subjects: - Adsorbates: Volatile Organic Compounds would be examined toward fabricating cancer detector sensors - Adsorbents: substrate supported borophene, multilayers borophene, charged borophene, or other polymorphs of borophene would be considered aiming toward realization these prospective sensors 48 REFERENCES [1] Albert, B., & Hillebrecht, H (2009) Boron: Elementary challenge for experimenters and theoreticians Angewandte Chemie - International Edition, 48(46), 8640–8668 https://doi.org/10.1002/anie.200903246 [2] Alvarez-Quiceno, J C., Schleder, G R., Marinho, E., & Fazzio, A (2017) Adsorption of d , d , and d transition metal atoms on β 12 —Borophene Journal of Physics: Condensed Matter, 29(30), 305302 https://doi.org/10.1088/1361-648X/aa75f0 [3] APIS (2016) Nitrogen Oxides (NOx) | Air Pollution Information System Retrieved June 2, 2019, from http://www.apis.ac.uk/overview/pollutants/overview_NOx.htm [4] Brotchie, A (2016) Borophene: Served on a silver platter Nature Reviews Materials, 1(11), 1–2 https://doi.org/10.1038/natrevmats.2016.83 [5] Bui, V Q., Pham, T T., Le, D A., Thi, C M., & Le, H M (2015) A firstprinciples investigation of various gas (CO, H2O, NO, and O2) absorptions on a WS2 monolayer: Stability and electronic properties Journal of Physics Condensed Matter, 27(30), 305005 https://doi.org/10.1088/09538984/27/30/305005 [6] Cai, Y., Ke, Q., Zhang, G., & Zhang, Y W (2015) Energetics, charge transfer, and magnetism of small molecules physisorbed on phosphorene Journal of Physical Chemistry C, 119(6), 3102–3110 https://doi.org/10.1021/jp510863p [7] Campbell, G P., Mannix, A J., Emery, J D., Lee, T L., Guisinger, N P., Hersam, M C., & Bedzyk, M J (2018) Resolving the Chemically Discrete Structure of Synthetic Borophene Polymorphs Nano Letters, 18(5), 2816– 2821 https://doi.org/10.1021/acs.nanolett.7b05178 [8] Campbell, G P., Mannix, A J., Emery, J D., Lee, T L., Guisinger, N P., 49 Hersam, M C., & Bedzyk, M J (2018) Resolving the Chemically Discrete Structure of Synthetic Borophene Polymorphs [Rapid-communication] Nano Letters, 18(5), 2816–2821 https://doi.org/10.1021/acs.nanolett.7b05178 [9] Cui, H., Zhang, X., & Chen, D (2018) Borophene: a promising adsorbent material with strong ability and capacity for SO2 adsorption Applied Physics A, 124(9), 636 https://doi.org/10.1007/s00339-018-2064-9 [10] Dinh Van, A (2016) Computational DFT-based Nanoscope [11] M., … Feng, B., Sugino, O., Liu, R Y., Zhang, J., Yukawa, R., Kawamura, Matsuda, I (2017) Dirac Fermions in Borophene Physical Review Letters, 118(9), 1–6 https://doi.org/10.1103/PhysRevLett.118.096401 [12] Feng, B., Zhang, J., Zhong, Q., Li, W., Li, S., Li, H., … Wu, K (2016) Experimental realization of two-dimensional boron sheets Nature Chemistry, 8(6), 563–568 https://doi.org/10.1038/nchem.2491 [13] Fowler, J D., Allen, M J., Tung, V C., Yang, Y., Kaner, R B., & Weiller, B H (2009) Practical chemical sensors from chemically derived graphene ACS Nano, 3(2), 301–306 https://doi.org/10.1021/nn800593m [14] Gao, N., Wu, X., Jiang, X., Bai, Y., & Zhao, J (2018) Structure and stability of bilayer borophene: The roles of hexagonal holes and interlayer bonding FlatChem, 7, 48–54 https://doi.org/10.1016/j.flatc.2017.08.008 [15] Henkelman group (2017) Code: Bader Charge Analysis [16] Huang, Y., Shirodkar, S N., & Yakobson, B I (2017) Two- Dimensional Boron Polymorphs for Visible Range Plasmonics: A FirstPrinciples Exploration Journal of the American Chemical Society, 139(47), 17181– 17185 https://doi.org/10.1021/jacs.7b10329 [17] K Momma and F Izumi (2011) “VESTA for three-dimensional visualization of crystal, volumetric and morphology data,” J Appl 50 Crystallogr., 44, 1272-1276 [18] Kaloni, T P., Schreckenbach, G., & Freund, M S (2014) Large enhancement and tunable band gap in silicene by small organic molecule adsorption Journal of Physical Chemistry C, 118(40), 23361–23367 https://doi.org/10.1021/jp505814v [19] Klimeš, J., Bowler, D R., & Michaelides, A (2010) Chemical accuracy for the van der Waals density functional Journal of Physics: Condensed Matter, 22(2), 022201 https://doi.org/10.1088/0953-8984/22/2/022201 [20] Klimeš, J., Bowler, D R., & Michaelides, A (2011) Van der Waals density functionals applied to solids Physical Review B, 83(19), 195131 https://doi.org/10.1103/PhysRevB.83.195131 [21] Kou, L., Frauenheim, T., & Chen, C (2014) Phosphorene as a Superior Gas Sensor: Selective Adsorption and Distinct I – V Response The Journal of Physical Chemistry Letters, 5(15), 2675–2681 https://doi.org/10.1021/jz501188k [22] Leenaerts, O., Partoens, B., & Peeters, F M (2008) Adsorption of H2 O, N H3, CO, N O2, and NO on graphene: A first-principles study Physical Review B - Condensed Matter and Materials Physics, 77(12), 1–6 https://doi.org/10.1103/PhysRevB.77.125416 [23] Levine, I (2014) Quantum Chemistry (7th ed.) [24] Liu, T., Chen, Y., Zhang, M., Yuan, L., Zhang, C., Wang, J., & Fan, J (2017) A first-principles study of gas molecule adsorption on borophene AIP Advances, 7(12), 0–9 https://doi.org/10.1063/1.5005959 [25] Liu, Yangyang, & Wilcox, J (2011) CO Adsorption on Carbon Models of Organic Constituents of Gas Shale and Coal Environmental Science & Technology, 45(2), 809–814 https://doi.org/10.1021/es102700c 51 [26] Liu, Yuanyue, Penev, E S., & Yakobson, B I (2013) Probing the synthesis of two-dimensional boron by first-principles computations Angewandte Chemie International Edition, 52(11), 3156–3159 https://doi.org/10.1002/anie.201207972 [27] Luo, Z., Fan, X., & An, Y (2017) First-Principles Study on the Stability and STM Image of Borophene Nanoscale Research Letters, 12 https://doi.org/10.1186/s11671-017-2282-7 [28] Mannix, A J., Zhou, X.-F., Kiraly, B., Wood, J D., Alducin, D., Myers, B D., … Guisinger, N P (2015) Synthesis of borophenes: Anisotropic, twodimensional boron polymorphs Science, 350(6267), 1513–1516 https://doi.org/10.1126/science.aad1080 [29] Mannix, Andrew J., Kiraly, B., Hersam, M C., & Guisinger, N P (2017) Synthesis and chemistry of elemental 2D materials Nature Reviews Chemistry, 1, 1–15 https://doi.org/10.1038/s41570-016-0014 [30] Mannix, Andrew J., Zhang, Z., Guisinger, N P., Yakobson, B I., & Hersam, M C (2018) Borophene as a prototype for synthetic 2D materials development Nature Nanotechnology, 13(6), 444–450 https://doi.org/10.1038/s41565-018-0157-4 [31] (2015) Mannix, Andrew J., Zhou, X.-F., Kiraly, B., & Guisinger, N P Synthesis of borophene: Anisotropic, two-dimensional boron polymorphs 350(6267), 1513–1516 [32] Mike Payne (1989) Vienna Ab intio Simulation Package [33] Mortazavi, B., Rahaman, O., Dianat, A., & Rabczuk, T (2016) Mechanical responses of borophene sheets: A first-principles study Physical Chemistry Chemical Physics, https://doi.org/10.1039/c6cp03828j 18(39), 27405–27413 [34] Nagarajan, V., & Chandiramouli, R (2018) Interaction Studies of Ammonia 52 Gas Molecules on Borophene Nanosheet and Nanotubes: A Density Functional Study Journal of Inorganic and Organometallic Polymers and Materials, 28(3), 920–931 https://doi.org/10.1007/s10904-017-0761-z [35] Peng, B., Zhang, H., Shao, H., Ning, Z., Xu, Y., Ni, G., … Zhu, H (2017) Stability and strength of atomically thin borophene from first principles calculations Materials Research Letters, 5(6), 399–407 https://doi.org/10.1080/21663831.2017.1298539 [36] Schedin, F., Geim, A K., Morozov, S V., Hill, E W., Blake, P., Katsnelson, M I., & Novoselov, K S (2007) Detection of individual gas molecules adsorbed on graphene Nature Materials, 6(9), 652–655 https://doi.org/10.1038/nmat1967 [37] (n.d.) Shukla, V., Grigoriev, A., Jena, N K., Ahuja, R., & Physics, A M Tuning the structural, electronic and intrinsic transport properties of twodimensional borophene sheets by strain [38] Shukla, V., Wärnå, J., Jena, N K., Grigoriev, A., & Ahuja, R (2017) Toward the Realization of 2D Borophene Based Gas Sensor Journal of Physical Chemistry C, 121(48), 26869–26876 https://doi.org/10.1021/acs.jpcc.7b09552 [39] Simon Cotton (2012) NO2 - Molecule of the Month - December 2012 (HTML version) Retrieved June 1, 2019, from http://www.chm.bris.ac.uk/motm/NO2/NO2h.htm [40] Skúlason, E (n.d.) Bader Analysis: Calculating the Charge on Individual Atoms in Molecules and Crystals [41] Sun, X., Liu, X., Yin, J., Yu, J., Li, Y., Hang, Y., … Guo, W (2017) Two-Dimensional Boron Crystals: Structural Stability, Tunable Properties, Fabrications and Applications Advanced Functional Materials, 27(19) https://doi.org/10.1002/adfm.201603300 53 [42] Tan, X., Tahini, H A., & Smith, S C (2017) Borophene as a Promising Material for Charge-Modulated Switchable CO Capture ACS Applied Materials & Interfaces, 9(23), 19825–19830 https://doi.org/10.1021/acsami.7b03676 [43] Vajary, R A., Tagani, M B., & Vishkayi, S I (2018) The effect of halogen atom adsorption on electrical and mechanical properties of β12 borophene sheet Modern Physics Letters B, 32(28), 1850347 https://doi.org/10.1142/s0217984918503475 [44] Valadbeigi, Y., Farrokhpour, H., & Tabrizchi, M (2015) Adsorption of small gas molecules on B36 nanocluster Journal of Chemical Sciences, 127(11), 2029–2038 https://doi.org/10.1007/s12039-015-0967-y [45] Wang, J., Deng, S., Liu, Z., & Liu, Z (2015) The rare two- dimensional materials with Dirac cones National Science Review, 2(1), 22–39 https://doi.org/10.1093/nsr/nwu080 [46] WHO (2017) Air pollution Retrieved December 7, 2018, from https://www.who.int/airpollution/en/ [47] Xia, W., Hu, W., Li, Z., & Yang, J (2014) A first-principles study of gas adsorption on germanene Phys Chem Chem Phys., 16(41), 22495–22498 https://doi.org/10.1039/C4CP03292F [48] Xiao, H., Cao, W., Ouyang, T., Guo, S., He, C., & Zhong, J (2017) Lattice thermal conductivity of borophene from first principle calculation Scientific Reports, 7(March), 1–8 https://doi.org/10.1038/srep45986 [49] Zhang, Y., & Yang, W (1998) Comment on ―Generalized Gradient Approximation Made Simple.‖ Physical Review Letters, 80(4), 890–890 https://doi.org/10.1103/PhysRevLett.80.890 [50] Zhang, Z., Mannix, A J., Hu, Z., Kiraly, B., Guisinger, N P., Hersam, M C., 54 & Yakobson, B I (2016) Substrate-Induced Nanoscale Undulations of Borophene on Silver Nano Letters, 16(10), 6622–6627 https://doi.org/10.1021/acs.nanolett.6b03349 [51] Zhang, Z., Penev, E S., & Yakobson, B I (2017) Two-dimensional boron: Structures, properties and applications Chemical Society Reviews, 46(22), 6746–6763 https://doi.org/10.1039/c7cs00261k [52] Zhao, S., Xue, J., & Kang, W (2014) Gas adsorption on MoS2 monolayer from first-principles calculations Chemical Physics Letters, 595– 596(2), 35– 42 https://doi.org/10.1016/j.cplett.2014.01.043 55 ... move the CO molecule along the surface of the adsorbent The darker color means the stronger adsorption energy of CO on borophene Thereby, CO tends to move along the vacant-defected lines of borophene... 1.2.2Gas molecules 1. 3Toxic gases adsorption on two-dimensional materials 1.3.1Gas adsorption on other tw 1.3. 2Adsorption application of b 1.4Thesis outline Chapter THEORETICAL BASICS...VIETNAM NATIONAL UNIVERSITY, HANOI VIETNAM JAPAN UNIVERSITY TA THI LUONG QUANTUM SIMULATION OF THE ADSORPTION OF TOXIC GASES ON THE SURFACE OF BOROPHENE MAJOR: NANOTECHNOLOGY