Department of Materials Science and Engineering, Pohang University of Science and Technology (POSTECH), Pohang 790-784, Republic of Korea.
Nanotechnology. 2013 Oct 25;24(42):424012. doi: 10.1088/0957-4484/24/42/424012. Epub 2013 Sep 25.
Nanosized LiFePO4 particles easily show a fast electrochemical response that can be achieved via a non-equilibrium pathway. To understand this intriguing phase transition behavior in nanosized LiFePO4 particles, the metastable solid-solution phase was prepared by thermal treatment with a chemically delithiated nanosized Li0.5FePO4 sample. Thermal treatment makes all the nanosized particles transform easily to the metastable solid-solution phase because of the large thermal energy while an electrochemical reaction does not. The phase separation behavior of the metastable solid-solution sample (Li0.5FePO4) was investigated under various kinetic conditions to understand critical factors affecting the phase separation behavior of nanosized LiFePO4 particles. The main findings in this study are as follows. The first finding is that the depressed phase separation behavior of the metastable phase may originate from the nanoparticle effect, in which the formation of a second phase inside a nanosized particle is not energetically favored because of the large interfacial energy. Therefore, phase separation in nanosized particles occurs between particles rather than inside a particle. If there was no over-potential, such as in the relaxed pellet experiment or in the relaxed electrode experiment in the electrolyte, the metastable phase was quite stable showing no phase separation behavior even though efficient pathways for lithium ions and electrons were well developed. The second finding is that the phase separation behavior of the metastable phase actually depends on the over-potential. Under open circuit voltage (OCV) conditions, the metastable phase started to exhibit a slight structural change during a long relaxation time, about ten days. The slow change of the metastable phase may be due to the low driving force, less than 10 mV, which comes from the energetic difference between the two-phase state and the metastable phase. This indicates that the phase separation behavior may require a large over-potential. When a large over-potential was applied using an external current, phase separation of the metastable phase was achieved, indicating that the phase separation behavior may be related to activation processes. Furthermore, the requirement for a large over-potential indirectly shows that the spinodal decomposition is depressed in nanosized particles. Considering that phase separation in nanosized particles occurs between particles, the surface charge transfer reaction can be a limited reaction for achieving phase separation because it is an activated process and governed by the over-potential. Considering the understanding obtained from the phase separation behavior of the metastable phase, the phase transition behavior of nanosized LiFePO4 particles during charging/discharging can proceed via the metastable phase because there is no spinodal decomposition behavior in nanosized particles and the metastable phase is quite stable.
纳米尺寸的 LiFePO4 颗粒容易表现出快速的电化学响应,可以通过非平衡途径实现。为了理解纳米尺寸 LiFePO4 颗粒中这种有趣的相转变行为,通过对化学脱锂的纳米 Li0.5FePO4 样品进行热处理,制备了亚稳固溶体相。由于热能较大,所有纳米颗粒在热处理过程中都很容易转化为亚稳固溶体相,而电化学反应则不会。在不同的动力学条件下研究了亚稳固溶体样品(Li0.5FePO4)的相分离行为,以了解影响纳米 LiFePO4 颗粒相分离行为的关键因素。本研究的主要发现如下。第一个发现是,亚稳相的相分离行为被抑制可能源于纳米颗粒效应,其中由于界面能较大,纳米颗粒内形成第二相在能量上是不利的。因此,纳米颗粒中的相分离发生在颗粒之间而不是颗粒内部。如果没有过电位,例如在松弛的颗粒实验或在电解质中的松弛电极实验中,亚稳相非常稳定,即使锂离子和电子的有效途径得到很好的发展,也没有相分离行为。第二个发现是,亚稳相的相分离行为实际上取决于过电位。在开路电压(OCV)条件下,亚稳相在长时间的弛豫时间内开始表现出轻微的结构变化,约十天。亚稳相的缓慢变化可能是由于驱动力低,小于 10 mV,这是由两相状态和亚稳相之间的能量差引起的。这表明相分离行为可能需要一个大的过电位。当施加外部电流以产生大的过电位时,亚稳相实现了相分离,表明相分离行为可能与激活过程有关。此外,对大过电位的要求间接表明在纳米颗粒中,旋节分解被抑制。考虑到纳米颗粒中的相分离发生在颗粒之间,表面电荷转移反应可能是实现相分离的受限反应,因为它是一个激活过程,由过电位控制。考虑到从亚稳相的相分离行为中获得的理解,纳米尺寸 LiFePO4 颗粒在充电/放电过程中的相转变行为可以通过亚稳相进行,因为纳米颗粒中没有旋节分解行为,而且亚稳相非常稳定。
