Subatomic deformation driven by vertical piezoelectricity from CdS ultrathin films.
Xuewen WangXuexia HeHongfei ZhuLinfeng SunWei FuXingli WangLai Chee HoongHong WangQingsheng ZengWu ZhaoJun WeiZhong JinZexiang ShenJie LiuTing ZhangZheng LiuPublished in: Science advances (2016)
Driven by the development of high-performance piezoelectric materials, actuators become an important tool for positioning objects with high accuracy down to nanometer scale, and have been used for a wide variety of equipment, such as atomic force microscopy and scanning tunneling microscopy. However, positioning at the subatomic scale is still a great challenge. Ultrathin piezoelectric materials may pave the way to positioning an object with extreme precision. Using ultrathin CdS thin films, we demonstrate vertical piezoelectricity in atomic scale (three to five space lattices). With an in situ scanning Kelvin force microscopy and single and dual ac resonance tracking piezoelectric force microscopy, the vertical piezoelectric coefficient (d 33) up to 33 pm·V(-1) was determined for the CdS ultrathin films. These findings shed light on the design of next-generation sensors and microelectromechanical devices.
Keyphrases
- single molecule
- atomic force microscopy
- high speed
- quantum dots
- high resolution
- high efficiency
- metal organic framework
- electron microscopy
- optical coherence tomography
- room temperature
- high throughput
- energy transfer
- visible light
- particulate matter
- air pollution
- climate change
- mass spectrometry
- working memory
- magnetic resonance imaging
- magnetic resonance
- low cost
- ionic liquid