Your search keyword '"Landa-Medrano, Imanol"' showing total 3 results

1. Making Room for Silicon: Including SiO x in a Graphite-Based Anode Formulation and Harmonization in 1 Ah Cells.

Author

Landa-Medrano, Imanol, Urdampilleta, Idoia, Castrillo, Iker, Grande, Hans-Jürgen, de Meatza, Iratxe, and Eguia-Barrio, Aitor

Subjects

*ANODES, *AUTOMOBILE industry, *ASSEMBLY line methods, *SILICON, *ELECTRODES, *CARBON nanotubes

Abstract

Transitioning to more ambitious electrode formulations facilitates developing high-energy density cells, potentially fulfilling the demands of electric car manufacturers. In this context, the partial replacement of the prevailing anode active material in lithium-ion cells, graphite, with silicon-based materials enhances its capacity. Nevertheless, this requires adapting the rest of the components and harmonizing the electrode integration in the cell to enhance the performance of the resulting high-capacity anodes. Herein, starting from a replacement in the standard graphite anode recipe with 22% silicon suboxide at laboratory scale, the weight fraction of the electrochemically inactive materials was optimized to 2% carbon black/1% dispersant/3% binder combination before deriving an advantage from including single-wall carbon nanotubes in the formulation. In the second part, the recipe was upscaled to a semi-industrial electrode coating and cell assembly line. Then, 1 Ah lithium-ion pouch cells were filled and tested with different commercial electrolytes, aiming at studying the dependency of the Si-based electrodes on the additives included in the composition. Among all the electrolytes employed, the EL2 excelled in terms of capacity retention, obtaining a 48% increase in the number of cycles compared to the baseline electrolyte formulation above the threshold capacity retention value (80% state of health). [ABSTRACT FROM AUTHOR]

Published

2024

2. Waterborne LiNi 0.5 Mn 1.5 O 4 Cathode Formulation Optimization through Design of Experiments and Upscaling to 1 Ah Li-Ion Pouch Cells.

Author

Lizaso, Lander, Urdampilleta, Idoia, Bengoechea, Miguel, Boyano, Iker, Grande, Hans-Jürgen, Landa-Medrano, Imanol, Eguia-Barrio, Aitor, and de Meatza, Iratxe

Subjects

LITHIUM-ion batteries, EXPERIMENTAL design, CATHODES, ELECTRIC vehicle industry

Abstract

High-voltage spinel LiNi0.5Mn1.5O4 (LNMO) is a promising candidate as a lithium-ion battery cathode material to fulfill the high-energy density demands of the electric vehicle industry. In this work, the design of the experiment's methodology has been used to analyze the influence of the ratio of the different components in the electrode preparation feasibility of laboratory-scale coatings and their electrochemical response. Different outputs were defined to evaluate the formulations studied, and Derringer–Suich's methodology was applied to obtain an equation that is usable to predict the desirability of the electrodes depending on the selected formulation. Afterward, Solver's method was used to figure out the formulation that provides the highest desirability. This formulation was validated at a laboratory scale and upscaled to a semi-industrial coating line. High-voltage 1 Ah lithium-ion pouch cells were assembled with LNMO cathodes and graphite-based anodes and subjected to rate-capability tests and galvanostatic cycling. 1 C was determined as the highest C-rate usable with these cells, and 321 and 181 cycles above 80% SOH were obtained in galvanostatic cycling tests performed at 0.5 C and 1 C, respectively. Furthermore, it was observed that the LNMO cathode required an activation period to become fully electrochemically active, which was shorter when cycled at a lower C-rate. [ABSTRACT FROM AUTHOR]

Published

2023

3. Future Material Developments for Electric Vehicle Battery Cells Answering Growing Demands from an End-User Perspective.

Author

Tidblad, Annika Ahlberg, Edström, Kristina, Hernández, Guiomar, de Meatza, Iratxe, Landa-Medrano, Imanol, Jacas Biendicho, Jordi, Trilla, Lluís, Buysse, Maarten, Ierides, Marcos, Horno, Beatriz Perez, Kotak, Yash, Schweiger, Hans-Georg, Koch, Daniel, and Kotak, Bhavya Satishbhai

Subjects

ELECTRIC vehicle batteries, ENERGY density, ENVIRONMENTAL standards, ELECTRIC vehicles, SAFETY standards

Abstract

Nowadays, batteries for electric vehicles are expected to have a high energy density, allow fast charging and maintain long cycle life, while providing affordable traction, and complying with stringent safety and environmental standards. Extensive research on novel materials at cell level is hence needed for the continuous improvement of the batteries coupled towards achieving these requirements. This article firstly delves into future developments in electric vehicles from a technology perspective, and the perspective of changing end-user demands. After these end-user needs are defined, their translation into future battery requirements is described. A detailed review of expected material developments follows, to address these dynamic and changing needs. Developments on anodes, cathodes, electrolyte and cell level will be discussed. Finally, a special section will discuss the safety aspects with these increasing end-user demands and how to overcome these issues. [ABSTRACT FROM AUTHOR]

Published

2021