Patents by Inventor ZILI XIE

ZILI XIE has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).

  • Publication number: 20240405156
    Abstract: An alternating electric field-driven gallium nitride (GaN)-based nano-light-emitting diode (nanoLED) structure with an electric field enhancement effect is provided. The GaN-based nanoLED structure forms a nanopillar structure that runs through an indium tin oxide (ITO) layer, a p-type GaN layer, a multiple quantum well (MQW) active layer and an n-type GaN layer and reaches a GaN buffer layer; and the nanopillar structure has a cross-sectional area that is smallest at the MQW active layer and gradually increases towards two ends of a nanopillar, forming a pillar structure with a thin middle and two thick ends. The shape of the GaN-based nanopillar improves the electric field strength within the QW layer in the alternating electric field environment and increases the current density in the QW region of the nanopillar structure under current driving, forming strong electric field gain and current gain, thereby improving the luminous efficiency of the device.
    Type: Application
    Filed: May 31, 2024
    Publication date: December 5, 2024
    Applicant: Nanjing University
    Inventors: Tao TAO, Rui ZHAO, Ting ZHI, Yu YAN, Zili XIE, Bin LIU
  • Publication number: 20230279549
    Abstract: An MPCVD device capable of realizing effective doping, comprises a reaction chamber and a gas input structure, wherein the gas input structure includes a first pipeline and a second pipeline for reaction gas, a first gas distributor, connected with the first pipeline, uniformly transports gas as a first reactant into the reaction chamber through a gas outlet of the first pipeline located near the top of the reaction chamber, the second pipeline uniformly inputs a doped reaction gas to a surface of a substrate through a second gas distributor with circular shape, a height of the gas transport ring connected with the second pipeline is substantially the same as that of a support for the substrate, and the gas transport ring can be concentrically placed at a center position inside the support, or the gas transport ring can also be concentrically placed outside the support.
    Type: Application
    Filed: March 1, 2023
    Publication date: September 7, 2023
    Inventors: Shulin Gu, Songmin Liu, Shunming Zhu, Jiandong Ye, kun Tang, Zili Xie, Rong Zhang, Youdou Zheng
  • Patent number: 11050004
    Abstract: A micro panchromatic QLED array device based on a quantum dot transfer process of deep silicon etching templates. Array-type square table structures pass through a p-type GaN layer and a quantum well active layer and are deep to an n-type GaN layer are disposed on a blue LED epitaxial wafer, wherein micro holes are formed through etching in the structures. Every 2*2 table structures constitute an RGB pixel unit. Among the four micro holes, three of the holes are filled with red light, green light and yellow light quantum dots respectively, and one of the holes emits blue light/is filled with a blue light quantum dot. Micro holes in a silicon wafer are formed through etching with a deep silicon etching technology; the micro holes in the silicon wafer are aligned with quantum dot filling areas on a micro-LED.
    Type: Grant
    Filed: November 11, 2019
    Date of Patent: June 29, 2021
    Assignee: NANJING UNIVERSITY
    Inventors: Bin Liu, Di Jiang, Junchi Yu, Xuan Wang, Danfeng Pan, Zili Xie, Yugang Zhou, Dunjun Chen, Xiangqian Xiu, Rong Zhang
  • Publication number: 20210057614
    Abstract: A micro panchromatic QLED array device based on a quantum dot transfer process of deep silicon etching templates. Array-type square table structures pass through a p-type GaN layer and a quantum well active layer and are deep to an n-type GaN layer are disposed on a blue LED epitaxial wafer, wherein micro holes are formed through etching in the structures. Every 2*2 table structures constitute an RGB pixel unit. Among the four micro holes, three of the holes are filled with red light, green light and yellow light quantum dots respectively, and one of the holes emits blue light/is filled with a blue light quantum dot. Micro holes in a silicon wafer are formed through etching with a deep silicon etching technology; the micro holes in the silicon wafer are aligned with quantum dot filling areas on a micro-LED.
    Type: Application
    Filed: November 11, 2019
    Publication date: February 25, 2021
    Applicant: NANJING UNIVERSITY
    Inventors: BIN LIU, Di JIANG, Junchi YU, Xuan WANG, Danfeng PAN, Zili XIE, Yugang ZHOU, Dunjun CHEN, Xiangqian XIU, Rong ZHANG
  • Patent number: 8420407
    Abstract: A kind of growth method of Fe3Nin the MOCVD system, comprising following process: 1) make the surface nitridation of sapphire substrate; 2) pump in carrier gas N2, ammonia and organic gallium sources, and grow low temperature GaN buffer on substrate; 3) raise temperature and grow the GaN supporting layer; 4) pump in FeCp2 as Fe sources, then grow Fe3N on the GaN supporting layer; the Fe3N granular films and the Fe3N single crystal films are obtained.
    Type: Grant
    Filed: May 3, 2010
    Date of Patent: April 16, 2013
    Assignee: Nanjing University
    Inventors: Rong Zhang, Zili Xie, Bin Liu, Xiangqian Xiu, Henan Fang, Hong Zhao, Xuemei Hua, Ping Han, Peng Chen, Youdou Zheng
  • Publication number: 20110269250
    Abstract: A kind of growth method of Fe3N, and the growth is in the MOCVD system, including following process: 1). the surface nitridation of sapphire substrate would be made; 2). pump in carrier gas N2, ammonia and organic gallium sources, and grow low temperature GaN buffer on substrate; 3). the temperature would be raised and grow the GaN supporting layer; 4). pump in FeCp2 as Fe sources, then grow Fe3N on the GaN supporting layer; the Fe3N granular films and the Fe3N single crystal films could be obtained. The invention realizes growing high quality Fe3N film. According to the problem of growing material with difficulty, the problems are solved by controlling and adjusting the conditions for the flux of organic gallium source and iron source, growth temperature, growth time, the flux of ammonia, and mole ratio of N and Ga. In the invention, the method is easy, the growth process could be controlled, and thus the growth method and the process control of growth technology have advancement.
    Type: Application
    Filed: May 3, 2010
    Publication date: November 3, 2011
    Applicant: Nanjing University
    Inventors: Rong Zhang, Zili Xie, Bin Liu, Xiangqian Xiu, Henan Fang, Hong Zhao, Xuemei Hua, Ping Han, Peng Chen, Youdou Zheng
  • Publication number: 20110237011
    Abstract: This invention presents a growth method for GaN based quantum wells red light LED structure by MOCVD epitaxy growth system, GaN based GaN/InGaN quantum wells red light LED structure material is obtained. The In mole fraction (x) for quantum well material InGaN is controlled between 0.1 and 0.5. This invention realizes the lumiscience of long wave length red light in group III nitrides. Aiming at the problem of difficulty in growing high In composition InGaN material, this invention solves this problem by controlling and adjusting the flux of organic Ga source and In source, growth temperature, time, and the flux of ammonia, and the mole ratio of N to Ga. By strictly controlling the conditions such as temperature and the flux ratio of reactant in the whole process, this invention determines the radiation wave length of quantum well, realizes the lumiscience of long wave length, and obtained GaN based GaN/InGaN quantum well red light LED structure.
    Type: Application
    Filed: March 29, 2010
    Publication date: September 29, 2011
    Applicant: NANJING UNIVERSITY
    Inventors: RONG ZHANG, ZILI XIE, BIN LIU, MING LI, XIANGQIAN XIU, DEYI FU, XUEMEI HUA, HONG ZHAO, PENG CHEN, PING HAN, YOUDOU ZHENG
  • Publication number: 20100288190
    Abstract: A kind of growth method of non-polarized-plane InN which is growing m-plane InN and In-rich m-plane InGaN on LiA1O2 (100) substrate by the metal organic chemical vapor deposition (MOCVD), and m-plane is one kind of non-polarized-plane, In-rich denotes that the component of In x is higher than 0.3 in InxGa1?xN. The invention synthetically grows m-plane InN and In-rich m-plane InGaN using LiA1O2 (100) as substrate which will be disposed and the buffer by MOCVD. And the non-polarized-plane InN would be produced through choosing appropriate substrate and the technique condition of growth as well as using the design of buffer by MOCVD.
    Type: Application
    Filed: March 28, 2010
    Publication date: November 18, 2010
    Applicant: NANJING UNIVERSITY
    Inventors: RONG ZHANG, ZILI XIE, BIN LIU, XIANGQIAN XIU, HONG ZHAO, XUEMEI HUA, PING HAN, DEYI FU, YI SHI, YOUDOU ZHENG