Conventional optical microscopes generally provide blurry and indistinguishable images for subwavelength nanostructures. However, a wealth of intensity and phase information is hidden in the corresponding diffraction-limited optical patterns and can be used for the recognition of structural features, such as size, shape, and spatial arrangement. Here, we apply a deep-learning framework to improve the spatial resolution of optical imaging for metal nanostructures with regular shapes yet varied arrangement. A convolutional neural network (CNN) is constructed and pre-trained by the optical images of randomly distributed gold nanoparticles as input and the corresponding scanning-electron microscopy images as ground truth. The CNN is then learne...
We demonstrate the all-optical reconstruction of gold nanoparticle geometry using super-resolution m...
We present a fast and precise deep-learning architecture, which we term O-Net, for obtaining super-r...
A wide range of techniques can be considered for segmentation of images of nanostructured surfaces. ...
We report the development of deep-learning coherent electron diffractive imaging at subangstrom reso...
Scanning electron microscopy (SEM) plays a crucial role in the characterization of nanoparticles. Un...
Over the past decade, deep learning has become one of the leading techniques used in the field of im...
We introduce a non-intrusive far-field optical microscopy, which reveals the fine structure of an ob...
A nonintrusive far-field optical microscopy resolving structures at the nanometer scale would revolu...
Background and objective: Nanoparticles present properties that can be applied to a wide range of fi...
International audienceSuperresolution light microscopy allows the imaging of labeled supramolecular ...
The aim of this thesis is to create a deep neural net capable of super-resolution on images acquired...
Automated particle segmentation and feature analysis of experimental image data are indispensable fo...
We report the experimental demonstration of deeply subwavelength far-field optical microscopy of unl...
We demonstrate the all-optical reconstruction of gold nanoparticle geometry using super-resolution m...
We present a fast and precise deep-learning architecture, which we term O-Net, for obtaining super-r...
A wide range of techniques can be considered for segmentation of images of nanostructured surfaces. ...
We report the development of deep-learning coherent electron diffractive imaging at subangstrom reso...
Scanning electron microscopy (SEM) plays a crucial role in the characterization of nanoparticles. Un...
Over the past decade, deep learning has become one of the leading techniques used in the field of im...
We introduce a non-intrusive far-field optical microscopy, which reveals the fine structure of an ob...
A nonintrusive far-field optical microscopy resolving structures at the nanometer scale would revolu...
Background and objective: Nanoparticles present properties that can be applied to a wide range of fi...
International audienceSuperresolution light microscopy allows the imaging of labeled supramolecular ...
The aim of this thesis is to create a deep neural net capable of super-resolution on images acquired...
Automated particle segmentation and feature analysis of experimental image data are indispensable fo...
We report the experimental demonstration of deeply subwavelength far-field optical microscopy of unl...
We demonstrate the all-optical reconstruction of gold nanoparticle geometry using super-resolution m...
We present a fast and precise deep-learning architecture, which we term O-Net, for obtaining super-r...
A wide range of techniques can be considered for segmentation of images of nanostructured surfaces. ...