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Papers

2024:

[1] X. Chen, Z.-Z. Lin*, Efficient Nitrogen Reduction on Weyl Antiferromagnet Mn3SnChemPhysChem  just accepted.  Supplementary I  Supplementary II

[2] M.-R. Li, X.-W. Chen, Z.-Z. Lin*, Enhanced non-metal catalyzed CO2 reduction on doped biphenyleneInt. J. Hydrogen Energy 62, 520-531 (2024). Supplementary

 

2023:

[1] X.-W. Chen, Z.-Z. Lin*, X.-M. Li, Biphenylene Network as Sodium Ion Battery Anode MaterialPhys. Chem. Chem. Phys.  25, 4340-4348 (2023).  Supplementary

[2] L.-R. Cheng, Z.-Z. Lin*, X.-M. Li and X. Chen*, 2D MoSi2N4 as electrode material of Li-air battery — A DFT studyJ. Nanopart. Res.  25, 55 (2023).  Supplementary

[3] X.-W. Chen, Z.-Z. Lin*, M.-R. Li, Surface-Independent CO2 and CO Reduction on Two-Dimensional Kagome Metal KV3Sb5Phys. Chem. Chem. Phys. 25, 26081-26093 (2023)  Supplementary

 

2022:

[1] Z.-Z. Lin*, X.-M. Li, X.-W. Chen and X. Chen*, CO2 Reduction on Single-Atom Ir Catalysts with Chemical Functionalizations, Phys. Chem. Chem. Phys.  24, 3733-3740 (2022).  Supplementary I  Supplementary II  Supplementary III  Supplementary IV

[2] X.-M. Li, Z.-Z. Lin*, L.-R. Cheng and X. Chen, Layered MoSi2N4 as electrode material of Zn-air batteryPhys. Status Solidi RRL 16, 2200007 (2022).  Supplementary I  Supplementary II  Supplementary III

[3] X. Chen and Z.-Z. Lin*, 2D spin transport through graphene-MnBi2Te4 heterojunction, Nanotechnology 33, 325201 (2022). 

[4] X.-M. Li, Z.-Z. Lin*, X.-W. Chen and X. Chen*, Selective CO2 Reduction on Topological Chern Magnet TbMn6Sn6Phys. Chem. Chem. Phys. 24, 18600-18607 (2022).  Supplementary I  Supplementary II

 

2021:

[1] L.-R. Cheng, Z.-Z. Lin*, X.-M. Li and X. Chen*, Can T-carbon serve as Li storage material and Li battery anode?Mat. Adv. 2, 4694-4701 (2021).  Supplementary I  Supplementary II(movie)  Supplementary III(movie)

[2] L.-R. Cheng and Z.-Z. Lin*, Toward Two-Dimensional Ionic Crystals with Intrinsic FerromagnetismPhys. Lett. A 395, 127229 (2021).   Appendix A: Supplementary

[3] X. Chen, Z.-Z. Lin* and L.-R. Cheng, Origin of itinerant ferromagnetism in two-dimensional Fe3GeTe2,Chin. Phys. B 30, 047502 (2021). Supplementary

 

2020:

[1] Z.-Z. Lin* and X. Chen, Ultrathin Scattering Spin Filter and Magnetic Tunnel Junction Implemented by Ferromagnetic 2D van der Waals Material, Adv. Elec. Mat. 6, 1900968 (2020). 

[2] Z.-Z. Lin*, X. Chen, C. Yin, L. Yue and F.-X. Meng, Electrochemical CO2 Reduction in Confined Space: Enhanced Activity of Metal Catalysts by Graphene Overlayer, Int. J. Energ. Res. 44, 784 (2020). 

[3] Z.-Z. Lin* and X. Chen, Tunable massive Dirac fermions in ferromagnetic Fe3Sn2 kagome latticePhys. Status Solidi RRL  14, 1900705 (2020).

[4] Z.-Z. Lin* and X. Chen, 1T GdN2 Monolayer — Spin-Orbit Induced Magnetic Dirac Semiconductor stable at Room TemperatureAppl. Surf. Sci. 529, 147129 (2020). 

 

2019:

[1] X. Chen*, Z.-Z. Lin, M. Ju and L.-X. Guo*, Confined electrochemical catalysis under cover: Enhanced CO2 reduction at the interface between graphdiyne and Cu surface, Appl. Surf. Sci. 479, 685 (2019). 

 

2018:

[1] X. Chen, Z.-Z. Lin* and M. Ju, Controllable Band Alignment Transition in InSe-MoS2 van der Waals HeterostructurePhys. Status Solidi RRL  12, 1800102 (2018). 

[2] X. Chen and Z.-Z. Lin*, A Primary Exploration to Quasi-Two-Dimensional Rare-Earth Ferromagnetic Particles: Holmium-Doped MoS2 Sheet as Room-Temperature Magnetic Semiconductor, J. Nanopart. Res. 20, 129 (2018).

[3] X. Chen and Z.-Z. Lin*, Single-layer graphdiyne-covered Pt(111) surface: Improved catalysis confined under two-dimensional overlayerJ. Nanopart. Res. 20, 136 (2018).

 

2017:

[1] Z.-Z. Lin*, Two-dimensional C12Mn2/C12Cr2 as room-temperature half metal/antiferromagnetic semiconductor: A systematical study, Phys. Chem. Chem. Phys. 19, 3394 (2017).

 

2016:

[1] Z.-Z. Lin*, Graphdiyne-supported single-atom Sc and Ti catalysts for high-efficient CO oxidation, Carbon 108, 343 (2016). 

[2] Z.-Z. Lin* and X. Chen, Transition-metal-decorated germanene as promising catalyst for removing CO contamination in H2Materials & Design 107, 82 (2016). 

[3] C. Yin, Z.-Z. Lin*, M. Li and H. Tang, Understanding the formation mechanism of two-dimensional atomic islands on crystal surfaces by the condensing potential modelZ. Naturforsch. A 71, 321 (2016). 

 

2015:

[1] Z.-Z. Lin*, Graphdiyne as a promising substrate for stabilizing Pt nanoparticle catalystCarbon 86, 301 (2015). 

[2] Z.-Z. Lin*, Theoretical investigation on isomer formation probability and free energy of small C clustersChin. Phys. B 24, 068201 (2015). 

[3] Z.-Z. Lin*, Tunable laser and photocurrents from linear atomic C chainsMod. Phys. Lett. B 29, 1550108 (2015). 

 

2014:

[1] Z.-Z. Lin*, Q. Wei and X. Zhu, Modulating the electronic properties of graphdyine nanoribbonsCarbon 66, 504 (2014). 

[2] Z.-Z. Lin* and X. Chen, Spin-polarized current generated by magnetic Fe atomic chain, Nanotechnology 25, 235202 (2014). 

[3] Z.-Z. Lin*, Theoretical investigation of thermodynamic balance between cluster isomers and statistical model for predicting isomerization rate, J. Nanopart. Res. 16, 2201 (2014).

[4] Z.-Z. Lin, W.-Y. Li, and X.-J. Ning*, A statistical model for predicting thermal chemical reaction rate, Chin. Phys. B 23, 050501 (2014). 

 

2013:

[1] Z.-Z. Lin* and X. Chen, Predicting the chemical stability of monatomic chainsEPL 101, 48002 (2013). 

[2] Z.-Z. Lin* and X. Chen, Single molecule capture by a doped monatomic carbon chain, J. Phys.: Codens Matter 25, 205302 (2013). 

[3] Z.-Z. Lin* and X. Chen, Ultrafast dynamics and fragmentation of C60 in intense laser pulsesPhys. Lett. A 377, 797 (2013).