Gumbiowski Nina, Barthel Juri, Loza Kateryna, Heggen Marc, Epple Matthias
Inorganic Chemistry, Centre for Nanointegration Duisburg-Essen (CENIDE), University of Duisburg-Essen 45117 Essen Germany
Ernst-Ruska Centre for Microscopy and Spectroscopy with Electrons, Forschungszentrum Jülich GmbH 52428 Jülich Germany.
Nanoscale Adv. 2024 Jul 1;6(16):4196-4206. doi: 10.1039/d4na00266k. eCollection 2024 Aug 6.
Machine learning approaches for image analysis require extensive training datasets for an accurate analysis. This also applies to the automated analysis of electron microscopy data where training data are usually created by manual annotation. Besides nanoparticle shape and size distribution, their internal crystal structure is a major parameter to assess their nature and their physical properties. The automatic classification of ultrasmall gold nanoparticles (1-3 nm) by their crystallinity is possible after training a neural network with simulated HRTEM data. This avoids a human bias and the necessity to manually classify extensive particle sets as training data. The small size of these particles represents a significant challenge with respect to the question of internal crystallinity. The network was able to assign real particles imaged by HRTEM with high accuracy to the classes monocrystalline, polycrystalline, and amorphous after being trained with simulated datasets. The ability to adjust the simulation parameters opens the possibility to extend this procedure to other experimental setups and other types of nanoparticles.
用于图像分析的机器学习方法需要大量的训练数据集才能进行准确分析。这也适用于电子显微镜数据的自动分析,其中训练数据通常通过手动标注来创建。除了纳米颗粒的形状和尺寸分布外,其内部晶体结构是评估其性质和物理特性的主要参数。在用模拟高分辨率透射电子显微镜(HRTEM)数据训练神经网络后,可以根据结晶度对超小金纳米颗粒(1-3纳米)进行自动分类。这避免了人为偏差以及将大量颗粒集作为训练数据进行手动分类的必要性。就内部结晶度问题而言,这些颗粒的小尺寸是一个重大挑战。在用模拟数据集训练后,该网络能够将通过HRTEM成像的真实颗粒高精度地归类为单晶、多晶和非晶类别。调整模拟参数的能力为将此程序扩展到其他实验设置和其他类型的纳米颗粒提供了可能性。
