--- name: advanced-energy-materials description: Use when targeting Advanced Energy Materials (Adv. Energy Mater.) or deciding whether an energy-materials manuscript fits this high-impact Wiley venue. Encodes the journal's fit, framing, method-and-evidence bar, house style, official-submission re-check, and desk-reject heuristics. --- # Advanced Energy Materials (advanced-energy-materials) ## Journal positioning Advanced Energy Materials is a Wiley journal in the Advanced family, dedicated to primary research on materials for energy generation, conversion, and storage. Its defining character is high-impact, materials-centered energy science: batteries and supercapacitors, solar cells (perovskite, organic, silicon, tandem), fuel cells, electrocatalysis and photocatalysis for energy, thermoelectrics, and hydrogen technologies. The journal rewards work where a genuine advance in the material — its composition, structure, interface, or processing — drives a measurable, benchmark-relevant gain in device or system performance, with mechanistic understanding of why. It sits alongside Advanced Materials but is energy-focused, and it expects performance claims to be calibrated against the best literature, not just against the authors' own controls. Readership is the broad energy-materials community spanning chemistry, materials science, and device engineering. This skill is a **fit / venue-selection / re-framing** tool. It does not replace the journal's current official submission guidelines. Before submitting, re-check the live author instructions on the Advanced Energy Materials Wiley site. ## When to trigger - The author names Advanced Energy Materials as the target for a primary research paper on an energy material with strong device or system relevance. - A manuscript reports a materials advance that improves a battery, solar cell, fuel cell, or (electro/photo)catalytic energy process, and the author is choosing between this venue and Joule, Energy & Environmental Science, or Advanced Materials. - A paper couples materials synthesis/design with mechanistic insight and benchmarked performance, and the author needs the fit, evidence bar, and desk-reject criteria before submission. - The author needs to decide whether the work is full-length materials research (here) versus a short high-impact letter (ACS Energy Letters). ## Scope & topic fit - Battery and electrochemical storage materials: electrodes, electrolytes (liquid, solid-state, polymer), interfaces and SEI/CEI chemistry for Li-ion, Na-ion, Li-metal, Li-S, and beyond-Li systems. - Photovoltaics: perovskite, organic, dye-sensitized, quantum-dot, silicon, and tandem solar cells where a materials or interface advance raises efficiency or stability. - Electrocatalysis and photocatalysis for energy: HER, OER, ORR, CO2 reduction, N2 reduction, and water splitting, with materials design driving activity, selectivity, or durability. - Fuel cells and electrolyzers: catalyst, membrane, and electrode materials for PEM, anion-exchange, and solid-oxide systems. - Thermoelectric, hydrogen-storage, and energy-harvesting materials where the materials advance is quantitatively linked to a figure of merit. - Materials-design and characterization advances (in situ/operando methods, interface engineering) that directly enable a benchmark-relevant energy-performance gain. ## Method & evidence bar - The materials advance and its performance consequence must be stated in one or two sentences; a paper that cannot link a specific material change to a measurable energy metric is misfit. - Performance must be benchmarked against the best current literature, not only the authors' baseline; key metrics (efficiency, capacity, rate, cycle/operational stability, overpotential, Faradaic efficiency) reported with conditions and uncertainty. - Device/cell testing must follow field-appropriate protocols: stated areas, loadings, current densities, cycling windows, and stability over a meaningful duration; certified or independently cross-checked efficiencies where claims are at the frontier. - Mechanistic understanding is expected: structure-property relationships supported by appropriate (ideally in situ/operando) characterization, not performance numbers alone. - Reproducibility evidence — multiple cells/devices, statistics on performance spread — is expected for any frontier claim. - Data supporting key claims should be available per Wiley/journal policy; characterization and electrochemical raw data should be reproducible. ## Structure & house style - Advanced Energy Materials uses the Advanced-family format; Full Papers, Communications, and Reviews are typical article types — re-check current types and limits on the live site. - The introduction is concise and frames the energy challenge and the specific materials gap; the readership is expert, so background is minimal and the advance is stated early. - Figures must be efficient and quantitative: each carries a key structure-property or performance result; performance plots should enable direct comparison to literature benchmarks. - A comprehensive Supporting Information carries full synthesis, characterization, device fabrication, and additional electrochemical/stability data. - Methods/Experimental Section must be complete enough for replication: synthesis, electrode/device fabrication, testing conditions, and characterization parameters. - Claims of records or "high performance" must be explicitly supported by a comparison table or benchmark against state of the art. ## Official-submission checklist - Before giving submission-ready advice, read `../../resources/source-basis.md` and `../../resources/official-source-map.md`; start from the official source anchors for this journal family, then cite the current journal-specific page you checked. - Search the live site for "Advanced Energy Materials author guidelines" and follow the current Wiley version. - Re-check current article types, word/figure limits, and abstract format; confirm Experimental Section and Supporting Information conventions. - Re-check data-availability and characterization-reporting requirements; confirm device-testing and efficiency-certification expectations. - Re-check competing-interests, funding, and AI-use disclosure requirements; confirm preprint policy (ChemRxiv/arXiv posting compatibility). - If the live official instructions conflict with this skill, the official instructions win. ## Pre-submission self-check - [ ] One sentence — the specific materials advance and the energy metric it improves, with the benchmark it beats. - [ ] Key performance metrics are reported with conditions, uncertainty, and a direct comparison to the best literature. - [ ] Device/cell testing follows field-appropriate protocols and reports loadings, areas, and meaningful stability/cycling. - [ ] Mechanistic structure-property evidence (ideally in situ/operando) supports the performance claim. - [ ] Reproducibility is demonstrated across multiple cells/devices with performance statistics. - [ ] The paper is positioned against recent Advanced Energy Materials / EES / Joule literature on this energy system. ## Common desk-reject triggers - A materials synthesis paper with no benchmark-relevant energy performance or device/system relevance. - Performance claims compared only to the authors' own baseline, without comparison to state-of-the-art literature. - Device or electrochemical data reported without conditions (areas, loadings, current densities, stability duration), preventing fair comparison. - A frontier efficiency or capacity claim with no certification, independent cross-check, or reproducibility statistics. - Incremental performance gains with no mechanistic insight or structure-property understanding. ## Re-routing decision - System-level energy science with techno-economic or sustainability framing beyond the material: `joule`. - Energy-and-environment scope where the advance is broader than a single material (analysis, devices, or sustainability): `energy-and-environmental-science`. - Functional-materials advance whose primary novelty is not energy-specific: `advanced-materials`. - Short, high-impact energy finding that fits a letter format: `acs-energy-letters`. ## Output format ```text [Fit] High / Medium / Low (one-line reason) [Target] Advanced Energy Materials [Topic tags] <2–3 closest topics> [Method/evidence] [Top risk] [Official items to re-check]
[Re-route suggestion] ```