Articles by Martin Morgeneyer in JoVE
实验装置的研制归还系数在真空条件下测量 Sven Drücker1, Isabell Krautstrunk2, Maria Paulick2, Khashayar Saleh1, Martin Morgeneyer1, Arno Kwade2 1Industrial Process Engineering, University of Technology of Compiègne, 2Institute for Particle Technology, Technische Universität Braunschweig 恢复系数是描述碰撞时的动能的损失的参数。这里，在真空条件下自由下落设置被显影以能够确定归还参数的系数为在微米范围内的颗粒的高的冲击速度。
实验协议来调查产品的粒子雾化在耐磨和环境下风化 Neeraj Shandilya1,2, Olivier Louis Le Bihan1, Christophe Bressot1, Martin Morgeneyer2 1Direction des Risques Chroniques, Institut National de l'Environnement Industriel et des Risques (INERIS), 2Génie des Procédés Industriels, Université de Technologie de Compiègne (UTC) 在这篇文章中，一个试验性协议，调查下磨损和风化环境下，提出了一种产品的粒子雾化。关于工程纳米材料的排放，在气雾剂的形式结果。具体实验装置进行详细说明。
Other articles by Martin Morgeneyer on PubMed
Emission of Titanium Dioxide Nanoparticles from Building Materials to the Environment by Wear and Weather Environmental Science & Technology. Feb, 2015 | Pubmed ID: 25590625 In the present work, we investigate the effect of weathering duration on a commercial photocatalytic nanocoating on the basis of its nanoparticle emission tendency into two media, air and water. It is found that increased weathering duration results in stepwise structural deterioration of the nanocoating, which in turn decreases the nanocoating life, changes the nanocoating removal mechanism, and increases the particle emission concentration. Emission of free TiO2 nanoparticles is found to be weathering duration dependent. Three quantities are introduced: emission transition pace (ETP), stable emission level (SEL), and stable emission duration (SED). By linear extrapolation of these quantities from short weathering durations, complete failure of the nanocoatings can be predicted and, moreover, the potential increase of nanoparticles release into the air.
Environmental Release of Engineered Nanomaterials from Commercial Tiles Under Standardized Abrasion Conditions Journal of Hazardous Materials. May, 2016 | Pubmed ID: 27321746 The study presented here focuses on commercial antibacterial tiles whose emissivity of (nano) particles due to abrasion has yet barely been investigated. The tiles have been characterized regarding their surface properties and composition throughout their chain-of-use, i.e. from their state of commercialization until the experimental end-of-service life. In contrast to plane standard tiles, their surfaces form hilly surfaces. In the depressions, titanium dioxide is found at the surface, thus theoretically protected by the hilly areas against abrasion on the tile's surface. Furthermore, a deposition technique has been put in place by producers allowing for coating the before mentioned commercial tiles with titanium dioxide, thus being similar to those commercially available. It consists in depositing titanium dioxide on the surface, latter one allowing fixing the first. This development allows for better understanding the future options for product formulation and thus improvement with respect to particle release. The tests reveal the aerosolization from commercial antibacterial tiles of micronic and submicronic particles in the inhalable region or particles that can subjected to be released in the environment (