获奖信息：

[1] 罗景庭（5/10）, 高世代声表面波材料与滤波器产业化技术，国务院，国家科学技术进步奖，二等奖，2018

[2] 罗景庭（5/15）, 高世代声表面波材料与滤波器产业化技术，教育部，教育部高等学校优秀成果奖科学技术进步奖，一等奖，2017

[3] 罗景庭（5/8）, 新型薄膜温差电池材料与器件研究,广东省人民政府，广东省自然科学奖，二等奖，2018

科研项目：

[1] 国家重点研究发展计划子课题项目：声表面波材料与器件，2016YFB0402705，国家科技部，2016.06-2020.5

[2] 深圳市学科布局项目：5G移动通信射频前端用TC-SAW滤波器的研究，JCYJ20180507182439574，深圳市科技创新委员会

科研论文：

[1] Kan Hao, Wei Zheng*, Richeng Lin, Min Li, Chen Fu, Huibin Sun, Mei Dong, Cunhua Xu, Jingting Luo* YongQing Fu, Feng Huang, Ultrafast Photovoltaic-Type Deep Ultraviolet Photodetectors Using Hybrid Zero-/Two-Dimensional Heterojunctions, ACS Applied Materials & Interfaces, 2019, 11, 8412−8418.

[2] Min Li, Hao Kan, Shutian Chen, Xiaoying Feng, Hui Li, Chong Li, Chen Fu, Aojie Quan, Huibin Sun, Jingting Luo*, Xueli Liu, Wang Wen*, Huan Liu, Qiuping Wei, Yongqing Fu, Colloidal quantum dot-based surface acoustic wave sensors for NO₂-sensing behavior, Sensors and Actuators B：Chemical, 2019, 287: 241-249

[3] Hui Li^#, Min Li^#, Hao Kan, Chong Li, Aojie Quan, Chen Fu, Jingting Luo*, Xueli Liu, Wang Wen*, Zhengbao Yang, Qiuping Wei, Yongqing Fu, Surface acoustic wave NO₂ sensors utilizing colloidal SnS quantum dot thin films, Surface & Coatings Technology, 2019, 362: 78-83

[4] Chen Fu, Yabing Ke, Aojie Quan, Xiaoming Fan, Chong Li, Jianliang Ou*, Jingting Luo*, Investigation of Rayleigh Wave and Love Wave Modes in 1120 ZnO Film Based Multilayer Structure, Surface and Coatings Technology, 2019, 363:330–37.

[3]Zheng ZH, Fan P, Luo JT*, Liang GX, Ma HL, Zhang XH, Yang C, Fu YQ, High-performance p-type inorganic-organic hybrid thermoelectric thin films, Nanoscale, 10, 13511-13519, 2018.

[4] Tao R, Hasan SA, Wang HZ, Zhou J, Luo JT*, McHale G, Gibson D, Canyelles-Pericas P, Cooke MD, Wood D, Liu Y, Wu Q, Ng WP, Franke T, Fu YQ. Bimorph material/structure designs for high sensitivity flexible surface acoustic wave temperature sensors. Scientific Reports, 8:9052 (2018).

[5] Lan CF, Lan HB, Liang GX, Zhao J, Peng HX, Fan B, Zheng ZH, Sun HB,Luo JT*, Fan P, Fu YQ, Simultaneous Formation of CH3NH3PbI3 and electron transport layers using antisolvent method for efficient perovskite solar cells. Thin Solid Films, 660, 75-81 (2018)

[6] Lan CF, Luo JT*, Lan HB, Fan B, Peng HX, Zhao J, Sun HB, Zheng ZH, , Enhanced Charge Extraction of Li-Doped TiO2 for Efficient Thermal-Evaporated Sb2S3 Thin Film Solar Cells Materials 11, 355, (2018)

[7] Li M, Luo JT*, Fu Chen, Kan H, Huang Zhen, Huang WM, Yang SQ, Zhang JB, Tang J, Fu YQ, Li HL, Liu H, PbSe quantum dots-based chemiresistors for room-temperature NO₂ detection. Sensors and Actuators B 256, 1045–1056, (2018).

[8] RahimaIshrat, ShahaMutabar, Khana Afzal, Luo JT∗, Zhong AH, Li M, Ahmed Rashid∗, Li HL, Wei QP, Fu YQ, Capacitive and resistive response of humidity sensors based ongraphene decorated by PMMA and silver nanoparticles, Sensors and Actuators B 267,42-50, (2018).

[9] Zhong AH, Sasaki, Fan P, Zhang DP, Luo JT*, Kazuhiro Hane, Integrated H2 nano-sensor array on GaN honeycomb nanonetwork fabricated by MEMS-based technology. Sensors and Actuators B 255, 2886–2893, (2018).

[10] Lan CF, Liang GX, Lan HB, Peng HX, Su ZH, Zhang DP, Sun HB, Luo JT*Fan P, Phys. Status Solidi RRL 2018, 1800025. Microstructural and Optical Properties of Sb2S3 Film Thermally Evaporated from Antimony Pentasulfide and Efficient Planar Solar Cells.

[11] Luo JT, Zheng ZH, Liang GX, Li F, Zhong AH, Ma HL, Zhang XH, Fan P. Study on the growth of Al-doped ZnO thin films with (1120) and (0002) preferential orientations and their thermoelectric characteristics, RSC Adv., 8, 6063–6068 (2018).

[12] Lan CF, Luo JT*, Lan HB, Fan B, Peng HX, Zhao J, Sun HB, Zheng ZH, Liang GX, Fan P, Enhanced Charge Extraction of Li-Doped TiO2 for Efficient Thermal-Evaporated Sb2S3 Thin Film Solar Cells Materials 11, 355, (2018)

[13] Fu C, Ke YB, Li M, Luo JT*, Li HL, Liang GX, Fan P, Design and Implementation of 2.45 GHz Passive SAW Temperature Sensors with BPSK Coded RFID Configuration. Sensors, 17, 1849 (2017).

[14] Fu C, Quan AJ, Luo JT*, Pang HF, Guo YJ, Wu Q, Ng WP, Zu XT, Fu YQ, Vertical jetting induced by shear horizontal leaky surface acoustic wave on 36° Y-X LiTaO3 Appl. Phys. Lett. 110, 173501 (2017).

[15] Luo JT, Zheng ZH, Liang GX, Li F, Fan P, Enhanced thermoelectric properties in AZO thin films by introducing Ti co-dopant, Materials Research Bulletin 94 (2017) 307–312

[16] Luo JT, Geraldi NR, Guan JH, McHale G, Wells GG, Fu YQ* Slippery Liquid-Infused Porous Surfaces (SLIPS) and Surface Acoustic Wave Droplet Transportation，7, 014017 (2017).

[17] Luo JT, Quan AJ, Fu C, Li HL, Shear-horizontal surface acoustic wave characteristics of a (110) ZnO/SiO2/Si multilayer structure. Journal of Alloys and Compounds, 693, 558–564, 2017

[18] Luo JT, Quan AJ, Liang GX, Zheng ZH, Ramanda S, Fu C, Li HL, Love-mode surface acoustic wave devices based on multilayers of TeO2/ZnO/Si(100) with high sensitivity and temperature stability. Ultrasonics, 75, 63-70, 2017.

[19] Liang GX, Fan P*, Luo JT*, Gu D, Zheng ZH, A promising unisource thermal evaporation for in situ fabrication of organolead halide perovskite CH₃NH₃PbI₃ thin film, Prog. Photovolt: Res. Appl. 23 (2015) 1901–1907

[20] Luo JT, Kang XY, Fan B, Zeng F, Pan F, Fan P, Jiang Z, Wang Y, Magnetism modulation in Cu-doped AlN via coupling between AlN thin film and ferroelectric substrate. Journal of Alloys and Compounds 618 (2015) 236–239.

[21] Lu SH, Zeng F, Dong WS, Liu A, Li XJ, Luo JT*. Controlling Ion Conductance and Channels to Achieve Synapticlike Frequency Selectivity. Nano-Micro Letter 7(2):121–126, 2015

[22] Luo JT, Li YZ, Kang XY, Zeng F, Pan F, Fan P, Jiang Z, Wang Y, Enhancement of room temperature ferromagnetism in Cu-doped AlN thin film by defect engineering. Journal of Alloys and Compounds 586 (2014) 469–474.

[23] Luo J T*, Xie M, Luo P X, Zhao B X, Du K, Pan F, Fan P. A sensitive glucose biosensor without using glucose test strips based on ZnO/SiO2/Si surface acoustic wave device. Materials Letters, 130 (2014) 14–16.

[24] Luo J T*, Luo P X, Xie M, Du K, Zhao B X, Pan F, Fan P, Zeng F, Zhang D P, Zheng ZH, Liang G X. A new type of glucose biosensor based on surface acoustic wave resonator using Mn-doped ZnO multilayer structure. Biosensors and Bioelectronics, 49, 512-518, 2013.

[25] Luo J T*, Pan F, Fan P, Zeng F, Zhang D P, Zheng Z H, Liang G X. Cost-effective and high frequency surface acoustic wave filters on ZnO:Fe/Si for low-loss and wideband application. Applied Physics Letters, 101, 172909, 2012.

[26] Luo J T, Yang Y C, Zhu X Y, Chen G, Zeng F, Pan, F*. Enhanced electromechanical response of Fe-doped ZnO films by modulating the chemical state and ionic size of the Fe dopant. Physical Review B, 82, 014116, 2010.

[27] Luo J T*, Fan P, Pan F, Zeng F, Zhang D P, Zheng Z H, Liang G X, Cai X M. Effects of Mn-doping on surface acoustic wave properties of ZnO films. Physica Status Solidi-Rapid Research Letters, 6, 436-438, 2012.

[28] Pan F*, Luo J T*, Yang Y C, Wang X B, Zeng F. Giant piezoresponse and promising application of environmental friendly small-ion-doped ZnO. Science China-Technological Sciences, 55, 421-436, 2012.

[29]Luo J T, Zhu X Y, Cheng G, Zeng F, Pan F*. Influence of the Mn concentration on the electromechanical response d33 of Mn-doped ZnO films. Physica Status Solidi-Rapid Research Letters, 4, 209-211, 2010.

[30]Luo J T, Zeng F, Pan F*, Li H F, Niu J B, Jia R, Liu M. Filtering performance improvement in V-doped ZnO/diamond surface acoustic wave filters. Applied Surface Science, 256, 3081-3085, 2010.

[31]Luo J T, Zhu X Y, Chen G, Zeng F, Pan, F*. The electrical, optical and magnetic properties of Si-doped ZnO films. Applied Surface Science, 258, 2177-2181, 2012.