Use my Search Websuite to scan PubMed, PMCentral, Journal Hosts and Journal Archives, FullText. Kick-your-searchterm to multiple Engines kick-your-query now !>

A dictionary by aggregated review articles of nephrology, medicine and the life sciences Your one-stop-run pathway from word to the immediate pdf of peer-reviewed on-topic knowledge.

10.1002/advs.202518091 http://scihub22266oqcxt.onion/10.1002/advs.202518091 41355538!?!41355538 Warning: file_get_contents(https://eutils.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&id=41355538&cmd=llinks): Failed to open stream: HTTP request failed! HTTP/1.1 429 Too Many Requests in C:\Inetpub\vhosts\kidney.de\httpdocs\pget.php on line 215       Adv+Sci+(Weinh) 2025 ; ? (?): e18091 Nephropedia Template TP {{tp|p=41355538|t=2025. High-Efficiency CO(2) Electrolysis Enabled by Interface-Engineered Composite Electrolytes in Ni-Based SOEC |pdf=|usr=}}{{41355538}} gab.com Text High-Efficiency CO(2) Electrolysis Enabled by Interface-Engineered Composite Electrolytes in Ni-Based SOEC JO: Adv Sci (Weinh) http://www.kidney.de/pget.php?&tw=1&pmid=41355538 #FOAvip Interfacial instability between different electrolyte materials is a critical challenge hindering the commercialization of CO(2) electrolysis via solid oxide electrolysis cells (SOECs). Specifically, the thermal deformation disparity at the yttria-stabilized zirconia (YSZ) and Gd-doped ceria (GDC) electrolyte interface leads to delamination during high-temperature operation, severely degrading cell performance and durability. In this study, this issue is resolved by designing a novel composite intermediate layer, fabricated through a simple dip-coating process using a mixture of YSZ and GDC powders. This composite layer effectively mitigates the thermal deformation disparity, ensuring excellent structural stability without delamination even after high-temperature sintering. Consequently, the cell incorporating the composite interlayer exhibits a significantly reduced interfacial resistance and achieves an exceptional current density of 2.14 A cm(-2) at 800 degrees C, which is among the highest performance levels reported for Ni-based fuel electrode-supported SOECs. Furthermore, the cell demonstrates excellent long-term stability, maintaining 91% of its initial performance after 80 h of continuous operation under a harsh 1.6 V condition. The electrolyte layer also retains robust and stable interfacial adhesion, confirming the durability of the engineered interface. This study presents an effective electrolyte interface engineering strategy for the development of high-performance and large-area SOECs for CO(2) electrolysis. Twit Text FOAVip High-Efficiency CO(2) Electrolysis Enabled by Interface-Engineered Composite Electrolytes in Ni-Based SOEC ????Adv Sci (Weinh) http://www.kidney.de/pget.php?&tw=1&pmid=41355538 #FOAvip Twit Text # Free Paper on # # # # # LINK http://www.kidney.de/pget.php?&tw=1&pmid=41355538 #FOAvip English Wikipedia <ref>{{Cite pmid|41355538}}</ref> High-Efficiency CO(2) Electrolysis Enabled by Interface-Engineered Composite Electrolytes in Ni-Based SOEC #MMPMID41355538 Yuldashev R; Jung H; Park JH; Lee JH; Kim MC Adv Sci (Weinh) 2025[Dec]; ? (?): e18091 PMID41355538show ga Interfacial instability between different electrolyte materials is a critical challenge hindering the commercialization of CO(2) electrolysis via solid oxide electrolysis cells (SOECs). Specifically, the thermal deformation disparity at the yttria-stabilized zirconia (YSZ) and Gd-doped ceria (GDC) electrolyte interface leads to delamination during high-temperature operation, severely degrading cell performance and durability. In this study, this issue is resolved by designing a novel composite intermediate layer, fabricated through a simple dip-coating process using a mixture of YSZ and GDC powders. This composite layer effectively mitigates the thermal deformation disparity, ensuring excellent structural stability without delamination even after high-temperature sintering. Consequently, the cell incorporating the composite interlayer exhibits a significantly reduced interfacial resistance and achieves an exceptional current density of 2.14 A cm(-2) at 800 degrees C, which is among the highest performance levels reported for Ni-based fuel electrode-supported SOECs. Furthermore, the cell demonstrates excellent long-term stability, maintaining 91% of its initial performance after 80 h of continuous operation under a harsh 1.6 V condition. The electrolyte layer also retains robust and stable interfacial adhesion, confirming the durability of the engineered interface. This study presents an effective electrolyte interface engineering strategy for the development of high-performance and large-area SOECs for CO(2) electrolysis. ?High-Efficiency CO(2) Electrolysis Enabled by Interface-Engineered Com(epmc).pdf DeepDyve Pubget Overpricing