It is well established that the miniaturization of batteries has not kept pace with the miniaturization of electronics. Three-dimensional (3D) batteries, which were developed with the intent of improving microbattery performance, have had limited success because of fabrication challenges and material constraints. Solid-state, 3D batteries have been particularly susceptible to these shortcomings. In this paper we demonstrate that the incorporation of a high conductivity, solid electrolyte is the key to achieving a non-planar solid-state battery with high areal-capacity and high power-density. The model, 2.5D platform used in this study is a modification of the more typical 3D configuration in that it is comprised of a cathode array of pillars (3D) and a planar (2D) anode. This 2.5D geometry exploits the use of a high conductivity, ionogel electrolyte (10~(-3) S cm~(-1)) which interpenetrates the 3D electrode array. The 2.5D battery offers high areal energy densities from the post array while the high-conductivity, solid electrolyte enables high power densities (3.7 m Wh cm~(-2) at 2.8 m W cm~(-2)). The reported solid-state 2.5D device exceeds the energy and power densities of any 3D solid-state system and the derived multiphysics model provides guidance for achieving significantly higher energy and power densities.
展开▼
机译:很好地确定,电池的小型化尚未与电子产品的小型化保持同步。由于制造挑战和材料限制,采用改善微滴乳性能而开发的三维(3D)电池具有有限的成功。固态,3D电池对这些缺点特别容易影响。在本文中,我们证明了高导电性,固体电解质是实现具有高面积能和高功率密度的非平面固态电池的关键。本研究中使用的模型,2.5D平台是更典型的3D配置的修改,因为它包括柱(3D)和平面(2D)阳极的阴极阵列。该2.5D几何形状利用使用高导电率,离子凝胶电解质(10〜(-3)Scm〜(-1)),该电导率互连3D电极阵列。 2.5D电池从柱子阵列提供高的面积能量密度,同时高导电率,固体电解质使高功率密度(3.7m WH cm〜(-2)在2.8 m W cm〜(-2))。报告的固态2.5D器件超过任何3D固态系统的能量和功率密度,衍生的多体学型号提供了实现显着更高的能量和功率密度的指导。
展开▼
