Li Fanghua

Source: Wikipedia, the free encyclopedia.
In this Chinese name, the family name is Li.
Li Fanghua
李方华
Born(1932-01-06)January 6, 1932
The World Academy of Sciences
Chinese name
Hanyu Pinyin
Lǐ Fānghuá

Li Fanghua (

Journal of Chinese Electron Microscopy Society, J. Electron Microscopy, Chinese Physics Letter, and Chinese Journal of Physics
.

Li won the

L'Oréal-UNESCO Awards for Women in Science in 2003.[1][2] She was fluent in English, French, German, Japanese, and Russian.[3]

Biography

Early years

Li Fanghua was born in Hong Kong in 1932. Because his father was a business partner in Hong Kong, he settled in Hong Kong. His father Li Jiong participated in the 1911 Revolution in his early years and served as a major general of the Fourth Army of the National Revolutionary Army.

Studies and research

In 1949, when he graduated from high school, Li Fanghua was sent to the Department of Physics of Lingnan University, and at the same time he was admitted to the Department of Astronomy of Sun Yat-sen University. In September, she entered Lingnan University. Because the teachers often use English to give lectures, she often consults English reference books after class, so she improves her English reading ability. In October, Guangzhou was liberated and public schools opened, and she transferred to the Department of Astronomy at Sun Yat-Sen University. But because of frequent suspension of classes and drumming and going to the street to do political propaganda, she wanted to change to a school with more studies.

  • In 1950, Li Fanghua was admitted to the Department of Physics of Wuhan University and was still in the first year.
  • In 1952, the state selected students from the second year of colleges and universities to take the exam for studying abroad in the Soviet Union. Wuhan University recommended Li Fanghua to take the exam and was admitted. In March, Li Fanghua entered the Preparatory Department of Beijing Russian Language School, specializing in Russian. In the autumn of the same year, I went to the Soviet Union and entered the Department of Physics of Leningrad University, a state university of the former Soviet Union. There were also three former students from the Department of Physics of Tsinghua University, Qing Chengrui, Gu Yifan and Huang Shengnian. In order to shorten the length of study, Li Fanghua and the four of them fought to transfer to the second grade together, and obtained the approval of the dean of the department.
  • In 1955, Li Fanghua was in teacher Mi. Asia. Under the guidance of Rums (М.Α.Яумшь), he began to prepare his graduation thesis, the title of which was "Study on Electron Diffraction of In-situ Evaporated Bismuth Metal Thin Films".
  • In 1956, Li Fanghua graduated from the Department of Physics of Leningrad University in the Soviet Union.
  • In 1960, Shi Ruwei (then director of the Institute of Physics, Chinese Academy of Sciences) arranged for Li Fanghua to independently carry out electron diffraction research, so that she could take the scientific knowledge learned in the Soviet Union into China. "Single crystal electron diffraction" structure analysis research.
  • In October 1982, Li Fanghua went to the Department of Applied Physics, Osaka University, Japan as a visiting scholar (until May 1983), and carried two new domestically produced minerals: Yellow River ore and bastnaesium ore, hoping to use Japanese super-high resolution There are new discoveries in domestic minerals by the electron microscope.[6]

Honors and awards

  • In 1984, Li Fanghua's research group won the second prize of the Chinese Academy of Sciences Scientific and Technological Achievement Award with the project "The establishment of lattice image and direct observation of crystal structure".[6]
  • In 1991, Li Fanghua won the Ye Qisun Physics Prize of the Chinese Physical Society.[6]
  • In 1992, Li Fanghua won the Hashimoto First Jiro Award (personal award) from the Chinese Society of Electron Microscopy.[6]
  • In 1993, Li Fanghua was elected as an academician of the Chinese Academy of Sciences.[6]
  • In 1996, Li Fanghua served as the chairman of the Chinese Society of Electron Microscopy (until 2000).[6]
  • In 1998, Li Fanghua was elected as an academician of the Third World Academy of Sciences.[6]
  • In 2002, at the time of her 70th birthday, the academic journal "Ultramicroscopy" of the International Society for Electron Microscopy published a special issue to celebrate her. 20 years ago, working photos in the conference room of the Institute of Physics of the Chinese Academy of Sciences, with Academician Li Fanghua on the right and Academician Fan Haifu on the second. Fan Haifu is an academician of the Chinese Academy of Sciences and an academician of the Third World Academy of Sciences. He is also the husband of Academician Li Fanghua.[6]
  • On February 27, 2003, Li Fanghua won the L'Oréal-UNESCO For Women in Science Awards and was the first Chinese scientist to receive the award.[6]
  • In 2009, Li Fanghua won the He Liang He Li Foundation Science and Technology Progress Award; the monograph "Electronic Crystallography and Image Processing" written in the same year was published.[6]

Personal life

Li was married to fellow physicist Fan Haifu.[4]

Main achievements

In 1985, Li Fanghua deduced a new and practical approximate analytical expression for high-resolution image intensity, established a practical image contrast theory, and solved the theoretical basis for the application of electronic crystallographic image processing in practice. Her research promotes the development of related disciplines and provides crystal structure information of new materials, which helps to draw the laws of the relationship between material properties, structure and technology. Her research content includes:[7]

High-resolution electron microscopy and electronic crystallography

In the early 1960s, Li Fanghua first carried out electron diffraction in China to determine the structure of a single crystal. In China, he determined the position of hydrogen atoms in the crystal for the first time. The relevant literature is still cited by foreign colleagues.[8]

In the 1970s, Li Fanghua and Fan Haifu cooperated to explore the combination of diffraction methods and high-resolution electron microscopy, and created a new image processing theory and technology in high-resolution electron microscopy. Later, she and her students established an unwinding processing technology based on the principle of maximum entropy. It provides an important way to determine the tiny crystal structure. It has been successfully applied to determine the crystal structure of materials such as high-temperature superconductors.[8]

While studying in Japan in the 1980s, Li Fanghua summarized new experimental rules and developed a method for determining the position of light atoms. On this basis, after returning to China, she proposed a new image contrast theory: "pseudo-weak phase object approximation". This theory clarified the relationship between image intensity and crystal thickness for the first time, and revealed the law of changes in the intensity of different atomic images. , Is the theoretical basis of the above-mentioned image processing technology. Under the guidance of this theory, Li Fanghua et al. observed lithium atoms in crystals for the first time experimentally. In addition, she participated in the early research of high-temperature superconducting materials by means of high-resolution electron microscopy, and was one of the first groups in the world to report the presence or absence of commensurate modulation structures of bismuth superconductors.[8]

Quasi-crystal

The research team led by Li Fanghua first discovered and reported the almost continuous transition process between quasicrystals and crystals, and she gave a theoretical explanation. Li Fanghua used the phase sub-strain field to derive some formulas reflecting the relationship between the quasicrystal and the crystal, and on this basis, proposed a new method to determine the structure of the quasicrystal, as well as the determination of the local phase sub-strain in the quasicrystal. method. And successfully applied to Al-Cu-Li and Al-Mn-Si quasicrystals.[8]

Crystal defects

For the newly developed field emission electron microscope, Li Fanghua proposed a new research direction for measuring crystal defects with atomic resolution. At present, she has successfully measured the 60-degree dislocation at the SiGe/Si epitaxial film interface into two incomplete dislocations of 90 degrees and 30 degrees, and a piece of stacking fault sandwiched between them. This is also the first report on the defect of atomic resolution at the interface of SiGe/Si epitaxial film.[8]

References

[5] [6] [7] [8]

  1. ^ a b c "Li Hailed as Top Woman Scientist". China Daily. April 2, 2003.
  2. ^ "贺李方华院士获"联合国教科文组织世界杰出女科学家成就奖"报告会举行". Chinese Society of Physics (in Chinese). 2003-03-22.
  3. ^ "李方华:显微科学的"半边天"". Sina (in Chinese). 2007-07-18.
  4. ^ "李方华:科学对性别无偏见". Beijing Review (in Chinese). 2010-03-17.
  5. ^ Jing, Wang. "46位科技人员获2009年度何梁何利基金奖". Chinese Academy of Science. Retrieved 18 June 2021.
  6. ^ Institute of Physics, Chinese Academy of Sciences. "研究员:李方华". 中国科学院物理研究所研究员李方华. Institute of Physics, Chinese Academy of Sciences. Retrieved 18 June 2021.
  7. ^ Chinese Academy of Sciences. "中科院院士李方华逝世 享年88岁". 凤凰网资讯. Chinese Academy of Sciences. Retrieved 18 June 2021.
  8. ^ Xiaowen, Wei. "人间失君少芳华-沉痛悼念本刊编委会副主任李方华院士!". 创新品牌网. 科技创新与品牌. Retrieved 18 June 2021.
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