2024
[23] Nondestructive Detection of Sunflower Seed Vigor and Moisture Content Based on Hyperspectral Imaging and Chemometrics. Foods. 2024. (IF=5.2, 中科院2区,通讯作者).
[22] Chiral structure induces spatial spiral arrangement of Fe3O4 nanoparticles to optimize electromagnetic wave dissipation. Appl. Phys. Lett, 2024.(IF= 4.0, 中科院2区, 第一作者/通讯作者).
[21] Combustion-Assisted construction of Defect-Enriched hierarchical carbon composites towards efficient Low-Frequency electromagnetic wave absorption,Chemical Engineering Journal,2024.(IF= 15.1, 中科院1区TOP, 第一作者/通讯作者)
2023
[19] Porous Carbonaceous Aerogels Composed of Multi-Scale Carbon-based Units for High-performance Microwave Absorption,ACS Applied Materials & Interfaces,(2023) (通讯作者,TOP,IF=9.5)
[18] Sea Urchin-Like SnS/Nitrogen-doped Carbon Nanotube Dielectric Composites for Tunable Electromagnetic Response,ACS Applied Nano Materials,(2023) (通讯作者,二区,IF=5.9)
[16] Study on detection method of microplastics in farmland soil based on hyperspectral imaging technology[J], Environmental Research ,2023(通讯作者,TOP, IF=8.4).
[15] ASFL-YOLOX: An Adaptive Spatial Feature Fusion and Lightweight Detection Method for Insect Pests of the Papilionidae Family[J],2023, Frontiers in Plant Science (通讯作者,TOP, IF=6.6).
[14] Simultaneous Optimization of Conduction and Polarization Losses in CNT@NiCo Compounds for Superior Electromagnetic Wave Absorption [J]. Journal of Materials Science & Technology, 2023, Accepted. (IF= 10.319, 中科院1区TOP, 第一作者/共同通讯作者)
[13] Classification and Adulteration of Mengding Mountain Green Tea Varieties Based on Fluorescence Hyperspectral Image Method,Journal of Food Composition and Analysis,(2023,共同通讯作者,二区,IF=4.5).
[12] Non-destructive Detection of Kiwifruit Soluble Solids Content based on Hyperspectral and Fluorescence Spectral Imaging[J]. Frontiers in Plant Science(2023) (通讯作者,TOP, IF=6.6).
[11] Real-time and Accurate Detection of Citrus under Complex Background Based on HPL-YOLOv4 Model[J].Computers and Electronics in Agriculture (2023) (通讯作者,1区TOP, IF=6.7).
[10] Design of an efficient combined multi-point picking scheme for the tea buds[J]. Frontiers in Plant Science(2023) (通讯作者,TOP, IF=6.6).
[9] Carbon-based Cages with Hollow Confined Structures for Efficient Microwave Absorption: State of the Art and Prospects[J]. Carbon (2023) (ESI高被引,通讯作者,TOP, IF=11.3,中科院一区).
2022
[8] Research on non-destructive testing of hotpot oil quality by Fluorescence Hyperspectral Technology combined with machine learning. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 121785.2022 (通讯作者,IF=4.8,中科院二区,ESI高被引).
[7] Controlled Fabrication of Core–Shell γ-Fe2O3@ C–Reduced Graphene Oxide Composites with Tunable Interfacial Structure for Highly Efficient Microwave Absorption[J]. J. Colloid Interf. Sci. 2022, 615: 685-696 (通讯作者,IF=9.9,中科院一区).
2021
[6] In situ construction of hierarchical core–shell Fe3O4@C nanoparticles–helical carbon nanocoil hybrid composites for highly efficient electromagnetic wave absorption[J]. Carbon, 2021, 171: 395-408. (第一作者,IF=11.3,中科院一区,ESI高被引论文).
[5] Structural engineering of hierarchical aerogels comprised of multi-dimensional gradient carbon nanoarchitectures for highly efficient microwave absorption[J]. Nano-Micro Lett., 2021, 13(1): 1-20. (第一作者,IF=23.6,中科院一区,ESI高被引论文).
2020
[4] Growth of carbon nanocoils by porous α-Fe2O3/SnO2 catalyst and its buckypaper for high efficient adsorption. Nano-Micro Lett., 2020, 12(1), 1-17. (第一作者,IF=23.6,中科院一区).
[3] Catalytic anisotropy induced by multi-particles for growth of carbon nanocoils. Carbon, 2020, 166, 101-112. (第一作者,IF=11.3,中科院一区).
[2] Crystallization-and morphology-tunable Fe3O4@C core–shell composites decorated on carbon nanotube skeleton with tailorable electromagnetic wave absorption behavior. Appl. Phys. Express, 2020, 13(12), 125501. (第一作者,IF=2.89,中科院三区).
[1] Facile synthesis of hybrid silver/porous carbon black substrate for surface-enhanced Raman scattering. Appl.Surf. Sci.,2020, 527, 146948. (IF=7.3,中科院一区,共同第一作者).