applied-energy
GitHub用于判断稿件是否契合Applied Energy期刊的系统级定位,提供范围匹配、方法严谨性评估及拒稿启发式规则。辅助将器件研究重构为系统问题或路由至合适期刊,不替代官方指南。
Trigger Scenarios
Install
npx skills add brycewang-stanford/Awesome-Journal-Skills --skill applied-energy -g -y
SKILL.md
Frontmatter
{
"name": "applied-energy",
"description": "Use when targeting Applied Energy or deciding whether a systems-level energy manuscript fits this venue. Encodes the journal's fit, the systems-scope-and-quantified-impact bar, modeling and assessment rigor, house style, the systems-vs-single-device routing, official-submission re-check, and desk-reject heuristics."
}
Applied Energy (applied-energy)
Journal positioning
Applied Energy (Elsevier) is a systems-level energy research venue: energy conversion and integration, energy-systems modeling and optimization, decarbonization pathways, demand and efficiency, and techno-economic and environmental assessment. Its center of gravity is the system, not the device — how technologies, sectors, and markets combine to deliver, store, or save energy, and what the quantified energetic, economic, and environmental consequences are. The single most common misfit is a single-material or single-component study (for example, one electrode or one catalyst) submitted as if it were systems research; such work belongs at a materials or device venue. A paper succeeds when its contribution is a generalizable systems-level insight backed by transparent, validated analysis. This skill is a fit / venue-selection / re-framing tool. It does not replace the journal's current official author guidelines. Before submitting, re-check the live Applied Energy Guide for Authors on the Elsevier site.
When to trigger
- The author names Applied Energy for an energy-systems modeling, integration, decarbonization, efficiency, or techno-economic/environmental-assessment manuscript.
- A paper must be re-framed from a device/component result into a systems-level question with quantified energy/economic/environmental impact — or re-routed if it is in fact device-level.
- The author is deciding between Applied Energy's systems scope and a device venue
(
journal-of-power-sources) or a materials venue (energy-storage-materials). - The author needs the journal's systems-scope and assessment rigor bar and desk-reject heuristics.
Scope & topic fit
- Energy-systems modeling and optimization: power, heat, transport, and multi-vector systems; dispatch, planning, and integration of variable renewables and storage.
- Energy conversion and integration at the system/process level, including hybrid and sector-coupled configurations and waste-heat/energy recovery.
- Decarbonization pathways and scenario analysis: emissions, cost, and feasibility of transitions across technologies, sectors, or regions.
- Demand-side, efficiency, buildings, and flexibility: demand response, load modeling, and end-use efficiency with system-level consequences.
- Techno-economic analysis (TEA) and life-cycle/environmental assessment (LCA) of energy technologies and systems, with transparent assumptions.
- Data-driven and machine-learning methods for energy systems when the contribution is a generalizable systems insight, not a black-box fit to one dataset.
Method & evidence bar
- The central claim is a systems-level insight: a result about how a system performs, integrates, or decarbonizes, with quantified energy, economic, and/or environmental outcomes — not a component performance number.
- Models must be transparent and validated/benchmarked where possible; assumptions, boundaries (system boundary, time horizon, spatial scope), and data sources stated.
- Techno-economic and environmental results require disclosed cost/emission factors, functional units, and uncertainty/sensitivity analysis; point estimates without sensitivity are weak.
- Generalizability and scenario robustness must be shown: results should hold or be characterized across cases, not depend on one favorable assumption set.
- Comparisons must use a fair baseline/counterfactual; reproducibility requires that data, parameters, and (where applicable) code be sufficiently described.
Structure & house style
- Standard research-article structure (introduction, methods/model, results, discussion); the journal uses highlights and a graphical abstract — re-check current article types and requirements on the live guide.
- The introduction frames the energy-systems gap and the decision/insight at stake, not a component novelty; methods state the system boundary, scope, and assumptions explicitly.
- Figures are load-bearing: system diagrams, scenario/optimization results, cost and emission breakdowns, and sensitivity/uncertainty plots.
- Supporting information carries full model formulations, parameter tables, and data; main-text figures must support the systems claim on their own.
Official-submission checklist
- Before giving submission-ready advice, read
../../resources/source-basis.mdand../../resources/official-source-map.md; start from the Elsevier anchors, then cite the current Applied Energy Guide for Authors page you checked. - Search the live site for "Applied Energy guide for authors" and follow the current Elsevier/Editorial Manager version.
- Re-check article types, highlights and graphical-abstract requirements, and length/figure expectations.
- Confirm data/code-availability expectations and assumption/parameter-reporting norms for TEA/LCA and modeling work.
- Re-check competing-interests, funding, author-contribution (CRediT), and AI-use disclosure requirements.
- If the live official instructions conflict with this skill, the official instructions win.
Pre-submission self-check
- The contribution is a systems-level insight with quantified energy/economic/environmental impact, not a single-device result.
- System boundary, time horizon, spatial scope, and key assumptions are stated explicitly.
- Models are transparent and validated/benchmarked; data sources are disclosed.
- TEA/LCA results include functional units, cost/emission factors, and uncertainty/sensitivity analysis.
- Results are shown to be robust across scenarios against a fair baseline/counterfactual.
- Highlights and graphical abstract represent the systems-level advance.
Common desk-reject triggers
- Single-material/single-device study (one electrode, one catalyst) framed as systems research.
- TEA/LCA with undisclosed assumptions, no functional unit, or no uncertainty/sensitivity analysis.
- Optimization/modeling tuned to one case with no generalizable systems insight.
- Black-box machine-learning fit to one dataset with no transferable energy-systems finding.
- Results that depend on a single favorable assumption set with no robustness check.
- Component-performance paper with system relevance asserted only in the abstract.
Re-routing decision
- Device-level electrochemical power (cells, fuel cells, supercapacitors) →
journal-of-power-sources. - Electrode/electrolyte materials and mechanism →
energy-storage-materials. - Applied catalysis/separation process at the unit level →
chemical-engineering-journal. - Authoritative energy/combustion review synthesis →
progress-in-energy-and-combustion-science. - Highest-profile cross-cutting energy advance →
nature-energy,joule, orenergy-and-environmental-science(different selectivity/format; re-check).
Output format
[Fit] High / Medium / Low (one-line reason)
[Target] Applied Energy
[Topic tags] <2–3 closest energy-systems subtopics>
[Systems insight] <the system-level claim and quantified impact in one line>
[Scope/boundary] <system boundary, horizon, and key assumptions stated?>
[Rigor] <validation + uncertainty/sensitivity + fair baseline present?>
[Top risk] <the single most likely reason for rejection>
[Official items to re-check] <article type / highlights / data-code / TEA-LCA reporting / disclosures>
[Re-route suggestion] <if device/material-level or out of scope, a better-matched venue>
Version History
- 1839142 Current 2026-07-05 12:54


