¸ð´øÇÏÀÌÅ×Å©
HOME > Á¤º¸Åë > ÀÚ·á½Ç

Liquid Crystal Microlenses Enable 4D Imaging

À̸§ : (ÁÖ)ºí·çÇò

2019-12-05 14:30:46 Á¶È¸ :4612


Liquid Crystal Microlenses Enable 4D Imaging



NANJING, China, Nov. 25, 2019 — Researchers from Nanjing University have developed a portable, inexpensive, and easy-to-use microlens to acquire 4D images. 4D imaging provides 3D resolution as well as polarization information.

Wei Hu, Yan Qing Lu, and colleagues used liquid crystals, materials found in most electronic displays. With a self-assembly process, they patterned arrays of liquid crystal microlenses into concentric circles.
A concentric array of liquid crystal microlenses provides 4D information about objects. Scale bar, 20 µm. Credit of ACS Nano 2019, DOI: 10.1021/acsnano.9b07104.
A concentric array of liquid crystal microlenses provides 4D information about objects. Scale bar, 20 ¥ìm. Courtesy of ACS Nano 2019, DOI: 10.1021/acsnano.9b07104.

The researchers used a polarized optical microscope to image objects, such as a cross or the letter ¡°E,¡± under different directions of linearly polarized light. Microlenses in the array imaged the object differently, depending on their distance from the object (depth) and the direction of polarized light, producing 4D information.

Light can become polarized by reflecting off objects that cause the lightwaves to undulate in a single plane. Unpolarized light, such as that from the sun, contains waves that move in every direction. Detecting polarized light can reveal information; for example, cancer cells can reflect polarized light differently than healthy tissues.

Although the resolution needs to be improved, the technique could someday be used in applications such as medical imaging, communications, displays, information encryption, and remote sensing, the researchers said.

The research was published in ACS Nano (www.doi.org/10.1021/acsnano.9b07104).





¹øÈ£ Á¦¸ñ   ³¯Â¥ Á¶È¸
[TracePro] Optical Modeling of Automotive LiDAR Systems (ÀÚµ¿Â÷ LiDAR ½Ã½ºÅÛÀÇ ±¤ÇÐ ¸ð..   20-07-22 3290
TracePro 2020 Release (Version 20.2)   20-05-11 3022
TracePro 2020 Release (Version 20.1)   20-03-17 3667
[WebEx] WebEx »ç¿ëÀÚ °¡ÀÌµå   20-03-09 2062
[WebEx] ½Ã½ºÄÚ Çù¾÷ Á¦Ç° ¼Ò°³¼­   20-03-09 2391
[Webex] ¾È½áº» »ç¶÷Àº À־ ÇÑ ¹ø¸¸ ½áº» »ç¶÷Àº ¾ø´Ù! - ¿þºñ³ª   20-03-05 2553
Agnisys, IDesignSpec 6.32 Ãâ½Ã ¹ßÇ¥   20-02-14 2431
Infrared laser method could diagnose brain concussions(Àû¿Ü¼± ·¹ÀÌÀú ¹æ¹ýÀ¸·Î ³úÁøÅÁ..   20-02-10 2625
Scientists Develop Spectrometer to Detect Molecular Signatures   20-01-16 2474
New optical material for cheaper polymer IR lenses is found via computational chemist..   20-01-13 2982
2020³â OSLO 20.1 Released   20-01-09 3015
[Power*tools] TCC ±×·¡ÇÁ ¼Ó ¹Ú½º¿¡ PD-0002°°Àº ±â±â ¸íÀ» Áý¾î ³Ö´Â ¹æ¹ý   20-01-07 3116
New Ceramic Nanocomposite Demonstrates High IR Transmittance, Thermal Stability   20-01-02 2690
3D-printed Optics: Focused femtosecond pulses print optical components with subdiffra..   20-01-02 3803
Ghost Imaging Speeds Up Super-Resolution Microscopy   19-12-26 3118
Algorithms for Optics: Generalized version of the inverse fast Fourier transform is..   19-12-24 2966
Hourglass nanowire photodiodes extend silicon's near-infrared response   19-12-20 2884
Tapered Optical Fiber Performs Multisite Photometry in the Brain   19-12-13 2716
TracePro 2019 Release (Version 19.6)   19-12-12 3118
28 [Agnisys] Adopting New Methods For Faster Development Of RISC-V based SoCs   19-12-10 2496
123
°Ë»ö