Towards regenerated cellulose fibers with high toughness K Moriam, D Sawada, K Nieminen, M Hummel, Y Ma, M Rissanen, H Sixta Cellulose 28, 9547-9566, 2021 | 46 | 2021 |
Air gap spinning of a cellulose solution in [DBNH][OAc] ionic liquid with a novel vertically arranged spinning bath to simulate a closed loop operation in the Ioncell® process C Guizani, S Larkiala, K Moriam, D Sawada, S Elsayed, S Rantasalo, ... Journal of Applied Polymer Science 138 (5), 49787, 2021 | 24 | 2021 |
New method for determining the degree of fibrillation of regenerated cellulose fibres Y Ma, M Rissanen, X You, K Moriam, M Hummel, H Sixta Cellulose 28, 31-44, 2021 | 20 | 2021 |
Hydrophobization of the man-made cellulosic fibers by incorporating plant-derived hydrophobic compounds K Moriam, M Rissanen, D Sawada, M Altgen, LS Johansson, DV Evtyugin, ... ACS Sustainable Chemistry & Engineering 9 (13), 4915-4925, 2021 | 19 | 2021 |
Fast and quantitative compositional analysis of hybrid cellulose-based regenerated fibers using thermogravimetric analysis and chemometrics C Guizani, M Trogen, H Zahra, L Pitkänen, K Moriam, M Rissanen, ... Cellulose 28 (11), 6797-6812, 2021 | 8 | 2021 |
Spinneret geometry modulates the mechanical properties of man-made cellulose fibers K Moriam, D Sawada, K Nieminen, Y Ma, M Rissanen, N Nygren, ... Cellulose 28, 11165-11181, 2021 | 7 | 2021 |
Downstream process: Liquid-Liquid extraction R Dahal, K Moriam, P Seppala Chemical Technology, AALTO University, 2016 | 2 | 2016 |
Corrected Gibbs-Thomson coefficient for the cellulose-cyclohexane system M Moriam | 1 | 2017 |
Modification of Ioncell spinning technology to increase fiber toughness and create a water-repellent surface K Moriam Aalto University, 2022 | | 2022 |