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Supporting Information. First Principles NMR Signatures of Graphene Oxide Ning Lu, Ying Huang, Haibei Li, Zhenyu Li, Jinlong Yang Email: [email protected]. Fig. S1: Detailed chemical shifts for the model in Fig.1(a). - PowerPoint PPT Presentation
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Supporting Information
First Principles NMR Signatures of Graphene Oxide
Ning Lu, Ying Huang, Haibei Li, Zhenyu Li, Jinlong Yang
Email: [email protected]
Fig. S1: Detailed chemical shifts for the model in Fig.1(a)
Fig. S2: Detailed chemical shifts for the 10-AGNR model corresponding to Fig.1(a)
Fig. S3: Detailed chemical shifts for the model in Fig.1(b)
Fig. S4: Detailed chemical shifts for the 10-AGNR model corresponding to Fig.1(b)
Fig. S5: Detailed chemical shifts for the model in Fig.1(c)
Fig. S6: Detailed chemical shifts for the model in Fig.1(d)
Fig. S7: Detailed chemical shifts for the model in Fig.2(a)
Fig. S8: Detailed chemical shifts for the10-AGNR model corresponding to Fig.2(a)
Fig. S9: Detailed chemical shifts for the model in Fig.2(b)
Fig. S10: Detailed chemical shifts for the 10-AGNR model corresponding to Fig.2(b)
Fig. S11: Detailed chemical shifts for the model in Fig.2(c)
Fig. S12: Detailed chemical shifts for the 10-AGNR model corresponding to Fig.2(c)
Fig. S13: Detailed chemical shifts for the model in Fig.2(d)
Fig. S14: Detailed chemical shifts for the model in Fig.2(e)
Fig. S15: Detailed chemical shifts for the 10-AGNR model corresponding to Fig.2(e)
Fig. S16: Detailed chemical shifts for the model in Fig.2(f)
Fig. S17: Detailed chemical shifts for the 10-AGNR model corresponding to Fig.2(f)
Fig. S18: Detailed chemical shifts for the model in Fig.3(a)
Fig. S19: Detailed chemical shifts for the 10-AGNR model corresponding to Fig.3(a)
Fig. S20: Detailed chemical shifts for the model in Fig.3(b)
Fig. S21: Detailed chemical shifts for the 10-AGNR model corresponding to Fig.3(b)
Fig. S22: Detailed chemical shifts for the model in Fig.3(c)
Fig. S23: Detailed chemical shifts for the 10-AGNR model corresponding to Fig.3(c)
Fig. S24: Detailed chemical shifts for the model in Fig.3(d)
Fig. S25: Detailed chemical shifts for the 10-AGNR model corresponding to Fig.3(d)
Fig. S26: Detailed chemical shifts for the model in Fig.3(e)
Fig. S27: Detailed chemical shifts for the model in Fig.3(f)
Fig. S28: Detailed chemical shifts for the model in Fig.4(a)
Fig. S29: Detailed chemical shifts for the model in Fig.4(b)
Fig. S30: Detailed chemical shifts for the model in Fig.4(c)
Fig. S31: Detailed chemical shifts for the model in Fig.4(d)
Fig. S32: Detailed chemical shifts for the model in Fig.5(a)
Fig. S33: Detailed chemical shifts for the model in Fig.5(b)
Fig. S33: Detailed chemical shifts for the model in Fig.5(c)
Fig. S35: Detailed chemical shifts for the model in Fig.5(d)
Fig. S36: Detailed chemical shifts for the model in Fig.5(e)
Fig. S38: Detailed chemical shifts for the model in Fig.3(a) with hydroxy groups removed
Fig. S37: Detailed chemical shifts for the model in Fig.3(b) with hydroxy groups removed
Fig. S39: Detailed chemical shifts for the model in Fig.4(a) with epoxy groups removed
Fig. S40: Detailed chemical shifts for the model in Fig.4(d) with epoxy groups removed
Fig. S41: Detailed chemical shifts for clean 9- and 10-AGNR
Fig. S42: Detailed chemical shifts for the model with fully-oxidized regions and sp2 carbon strips between them proposed in PRL 103, 086802 (2009)
Fig. S43: The histograms of chemical shifts for the models in Fig. 4.
