@article{nokey,

title = {A low-cost and high-energy aqueous potassium-ion battery},

author = {R L Streng and T Steeger and A Senyshyn and S Abel and P Schneider and C Benning and B M Naranjo and D Gryc and M Z Hussain and O Lieleg and M Elsner and A S Bandarenka and K Cicvari\'{c}},

url = {https://www.sciencedirect.com/science/article/pii/S2095495625001871},

doi = {https://doi.org/10.1016/j.jechem.2025.02.039},

issn = {2095-4956},

year  = {2025},

date = {2025-07-01},

journal = {Journal of Energy Chemistry},

volume = {106},

pages = {523-531},

abstract = {To address challenges related to the intermittency of renewable energy sources, aqueous potassium-ion batteries (AKIBs) are a promising and sustainable alternative to conventional systems for large-scale energy storage. To enable their practical application, maximizing energy density and longevity while minimizing production and material costs is a key goal. In this work, we propose an AKIB consisting only of abundant and cost-efficient materials, which delivers a high energy density of more than 70 Wh kg−1. We combine simple strategies to stabilize the Mn-rich Prussian blue analog cathode by Fe-doping, improving the crystallinity, and tuning the electrolyte composition without employing expensive water-in-salt electrolytes. Using a mixed 2.5 M Ca(NO3)2 + 1.5 M KNO3 electrolyte, we assemble a novel AKIB with a Fe-doped manganese hexacyanoferrate cathode and an organic poly(naphthalene-4-formyl-ethylenediamine) anode. Besides a high energy density, the full cell delivers a specific capacity of approximately 60 mA h g−1, a power density of 5000 W kg−1, and 80% capacity retention after 600 cycles.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

@article{nokey,

title = {The Interaction of Sub-Monolayer Ta Adatoms and Clusters with Oxygen at the Pt(111) Interface},

author = {K Bertrang and T Hinke and S Kaiser and M Knechtges and F Loi and P Lacovig and M Jahangirzadeh Varjovi and F Esch and A Baraldi and S Tosoni and A Kartouzian and U Heiz},

url = {https://doi.org/10.1021/acs.jpcc.5c00699},

doi = {10.1021/acs.jpcc.5c00699},

issn = {1932-7447},

year  = {2025},

date = {2025-04-03},

journal = {The Journal of Physical Chemistry C},

volume = {129},

number = {13},

pages = {6511-6523},

abstract = {The interaction of submonolayer quantities of size-selected and soft-landed Tan (n = 4, 5, 6, 8, 13) clusters with Pt(111) is investigated employing high-resolution X-ray photoelectron spectroscopy (HR-XPS), scanning tunneling microscopy (STM), and density functional theory (DFT) simulations. The deposited clusters are monodispersed and stable under ultrahigh vacuum (UHV) conditions at 40 K. They display a size-specific trend in photoemission spectra, which is reasoned in terms of the distinct in plane coordination of Ta atoms in the clusters. Both the Ta coordination number and distance from the Pt surface influence its Bader charge and, accordingly, the oxidation state of the atoms in the Ta cluster. They already fragment in the presence of low amounts of oxygen and form a common oxidation product observed for all cluster sizes. Based on our observations, we propose an oxidation mechanism in the example of Ta8 clusters, which is closely comparable to the one discussed in gas-phase studies on the oxidation of cationic Ta clusters of similar size. Concomitant to oxidation-induced fragmentation, the agglomeration into Ta-oxide islands with Ta in an oxidation state of +5 is observed. However, the strong interaction with the Pt surface leads to Ta 4f orbital photoemission features that differ from those commonly observed for Ta2O5. Computational insights concerning the structure of the Ta-oxide islands indicate flat agglomerates that agree with STM observations. They suggest distinct Ta 4f photoemission contributions from interfacial and surface-related Ta configurations. The respective HR-XPS spectra display specific core-level shifts as a function of bonding configuration and vicinity to the Pt surface. By annealing at 900 K in UHV, we observe oxygen loss and concomitant intermixing of Ta atoms with the Pt subsurface lattice to which results in the formation of a Ta\textendashPt alloy. These species, Ta-oxide islands, and Ta\textendashPt alloy, can reversibly interconvert by oxidative surface segregation and reductive intermixing.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

@article{nokey,

title = {Lanthanide single-atom catalysts for efficient CO2-to-CO electroreduction},

author = {Q Wang and T Luo and X Cao and Y Gong and Y Liu and Y Xiao and H Li and F Gr\"{o}bmeyer and Y-R Lu and T-S Chan and C Ma and K Liu and J Fu and S Zhang and C Liu and Z Lin and L Chai and E Cortes and M Liu},

url = {https://doi.org/10.1038/s41467-025-57464-8},

doi = {10.1038/s41467-025-57464-8},

issn = {2041-1723},

year  = {2025},

date = {2025-03-27},

journal = {Nature Communications},

volume = {16},

number = {1},

pages = {2985},

abstract = {Single-atom catalysts (SACs) have received increasing attention due to their 100% atomic utilization efficiency. The electrochemical CO2 reduction reaction (CO2RR) to CO using SAC offers a promising approach for CO2 utilization, but achieving facile CO2 adsorption and CO desorption remains challenging for traditional SACs. Instead of singling out specific atoms, we propose a strategy utilizing atoms from the entire lanthanide (Ln) group to facilitate the CO2RR. Density functional theory calculations, operando spectroscopy, and X-ray absorption spectroscopy elucidate the bridging adsorption mechanism for a representative erbium (Er) single-atom catalyst. As a result, we realize a series of Ln SACs spanning 14 elements that exhibit CO Faradaic efficiencies exceeding 90%. The Er catalyst achieves a high turnover frequency of ~130,000 h−1 at 500 mA cm−2. Moreover, 34.7% full-cell energy efficiency and 70.4% single-pass CO2 conversion efficiency are obtained at 200 mA cm−2 with acidic electrolyte. This catalytic platform leverages the collective potential of the lanthanide group, introducing new possibilities for efficient CO2-to-CO conversion and beyond through the exploration of unique bonding motifs in single-atom catalysts.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}