Lee Jongmin, Noh Jongsu, Nguyen Vy Thuy, Ahn Chi-Yeong, Shin Hyeyoung, Chung Dong Young
Department of Chemical and Biomolecular Engineering, Korea Advanced Institute of Science and Technology, Daejeon, 34141, Korea.
Graduate School of Energy Science and Technology (GEST), Chungnam National University, Daejeon, 34134, Korea.
ChemSusChem. 2025 Jul 1;18(13):e202402763. doi: 10.1002/cssc.202402763. Epub 2025 Apr 21.
While recent advancements in electrocatalysts have led to significant progress toward the commercialization of electrochemical energy conversion devices, performance degradation derived by airborne impurity remains a critical challenge to address. In particular, chloride (Cl) poisoning of platinum (Pt) catalysts remains a critical challenge for performance. Herein, an effective strategy for suppressing Cl poisoning from the perspective of ionomer layer engineering is demonstrated. From the hybrid interface of cation and anion exchange ionomers, the local microenvironment at the catalyst surface is modified, resulting in significant suppression of Cl poisoning. In situ inductively coupled plasma-mass spectrometry analysis revealed that the local Cl concentration at the Pt surface decreased by 40% compared to the bulk concentration. These findings highlight the synergistic role of the hybrid ionomer interface in suppressing Cl poisoning, validating its effectiveness in maintaining activity and mitigating Pt dissolution. This ionomer engineering approach provides a promising pathway for improving the reliability of electrocatalytic systems under challenging operational conditions.
虽然电催化剂的最新进展已在电化学能量转换装置商业化方面取得显著进展,但空气中杂质导致的性能退化仍是一个亟待解决的关键挑战。特别是,铂(Pt)催化剂的氯(Cl)中毒仍然是影响性能的关键挑战。在此,展示了一种从离聚物层工程角度抑制Cl中毒的有效策略。通过阳离子和阴离子交换离聚物的混合界面,催化剂表面的局部微环境得到改变,从而显著抑制了Cl中毒。原位电感耦合等离子体质谱分析表明,与本体浓度相比,Pt表面的局部Cl浓度降低了40%。这些发现突出了混合离聚物界面在抑制Cl中毒中的协同作用,验证了其在维持活性和减轻Pt溶解方面的有效性。这种离聚物工程方法为在具有挑战性的操作条件下提高电催化系统的可靠性提供了一条有前景的途径。
