Research Idea Brainstorming
Structured frameworks for discovering the next research idea. This skill provides ten complementary ideation lenses that help researchers move from vague curiosity to concrete, defensible research proposals. Each framework targets a different cognitive mode—use them individually or combine them for comprehensive exploration.
When to Use This Skill
- Starting a new research direction and need structured exploration
- Feeling stuck on a current project and want fresh angles
- Evaluating whether a half-formed idea has real potential
- Preparing for a brainstorming session with collaborators
- Transitioning between research areas and seeking high-leverage entry points
- Reviewing a field and looking for underexplored gaps
Do NOT use this skill when:
- You already have a well-defined research question and need execution guidance
- You need help with experimental design or methodology (use domain-specific skills)
- You want a literature review (use
scientific-skills:literature-review)
Core Ideation Frameworks
1. Problem-First vs. Solution-First Thinking
Research ideas originate from two distinct modes. Knowing which mode you are in prevents a common failure: building solutions that lack real problems, or chasing problems without feasible approaches.
Problem-First (pain point → method):
- Start with a concrete failure, bottleneck, or unmet need
- Naturally yields impactful work because the motivation is intrinsic
- Risk: may converge on incremental fixes rather than paradigm shifts
Solution-First (new capability → application):
- Start with a new tool, insight, or technique seeking application
- Often drives breakthroughs by unlocking previously impossible approaches
- Risk: "hammer looking for a nail"—solution may lack genuine demand
Workflow:
- Write down your idea in one sentence
- Classify it: Is this problem-first or solution-first?
- If problem-first → verify the problem matters (who suffers? how much?)
- If solution-first → identify at least two genuine problems it addresses
- For either mode, articulate the gap: what cannot be done today that this enables?
Self-Check:
- Can I name a specific person or community who needs this?
- Is the problem I am solving actually unsolved (not just under-marketed)?
- If solution-first, does the solution create new capability or just replicate existing ones?
2. The Abstraction Ladder
Every research problem sits at a particular level of abstraction. Deliberately moving up or down the ladder reveals ideas invisible at your current level.
| Direction | Action | Outcome |
|---|---|---|
| Move Up (generalize) | Turn a specific result into a broader principle | Framework papers, theoretical contributions |
| Move Down (instantiate) | Test a general paradigm under concrete constraints | Empirical papers, surprising failure analyses |
| Move Sideways (analogize) | Apply same abstraction level to adjacent domain | Cross-pollination, transfer papers |
Workflow:
- State your current research focus in one sentence
- Move UP: What is the general principle behind this? What class of problems does this belong to?
- Move DOWN: What is the most specific, constrained instance of this? What happens at the extreme?
- Move SIDEWAYS: Where else does this pattern appear in a different field?
- For each new level, ask: Is this a publishable contribution on its own?
Example:
- Current: "Improving retrieval accuracy for RAG systems"
- Up: "What makes context selection effective for any augmented generation system?"
- Down: "How does retrieval accuracy degrade when documents are adversarially perturbed?"
- Sideways: "Database query optimization uses similar relevance ranking—what can we borrow?"
3. Tension and Contradiction Hunting
Breakthroughs often come from resolving tensions between widely accepted but seemingly conflicting goals. These contradictions are not bugs—they are the research opportunity.
Common Research Tensions:
| Tension Pair | Research Opportunity |
|---|---|
| Performance ↔ Efficiency | Can we match SOTA with 10x less compute? |
| Privacy ↔ Utility | Can federated/encrypted methods close the accuracy gap? |
| Generality ↔ Specialization | When does fine-tuning beat prompting, and why? |
| Safety ↔ Capability | Can alignment improve rather than tax capability? |
| Interpretability ↔ Performance | Do mechanistic insights enable better architectures? |
| Scale ↔ Accessibility | Can small models replicate emergent behaviors? |
Workflow:
- Pick your research area
- List the top 3-5 desiderata (things everyone wants)
- Identify pairs that are commonly treated as trade-offs
- For each pair, ask: Is this trade-off fundamental or an artifact of current methods?
- If artifact → the reconciliation IS your research contribution
- If fundamental → characterizing the Pareto frontier is itself valuable
Self-Check:
- Have I confirmed this tension is real (not just assumed)?
- Can I point to papers that optimize for each side independently?
- Is my proposed reconciliation technically plausible, not just aspirational?
4. Cross-Pollination (Analogy Transfer)
Borrowing structural ideas from other disciplines is one of the most generative research heuristics. Many foundational techniques emerged this way—attention mechanisms draw from cognitive science, genetic algorithms from biology, adversarial training from game theory.
Requirements for a Valid Analogy:
- Structural fidelity: The mapping must hold at the level of underlying mechanisms, not just surface similarity
- Non-obvious connection: If the link is well-known, the novelty is gone
- Testable predictions: The analogy should generate concrete hypotheses
High-Yield Source Fields for ML Research:
| Source Field | Transferable Concepts |
|---|---|
| Neuroscience | Attention, memory consolidation, hierarchical processing |
| Physics | Energy-based models, phase transitions, renormalization |
| Economics | Mechanism design, auction theory, incentive alignment |
| Ecology | Population dynamics, niche competition, co-evolution |
| Linguistics | Compositionality, pragmatics, grammatical induction |
| Control Theory | Feedback loops, stability, adaptive regulation |
Workflow:
- Describe your problem in domain-agnostic language (strip the jargon)
- Ask: What other field solves a structurally similar problem?
- Study that field's solution at the mechanism level
- Map the solution back to your domain, preserving structural relationships
- Generate testable predictions from the analogy
- Validate: Does the borrowed idea actually improve outcomes?
5. The "What Changed?" Principle
Strong ideas often come from revisiting old problems under new conditions. Advances in hardware, scale, data availability, or regulations can invalidate prior assumptions and make previously impractical approaches viable.
Categories of Change to Monitor:
| Change Type | Example | Research Implication |
|---|---|---|
| Compute | GPUs 10x faster | Methods dismissed as too expensive become feasible |
| Scale | Trillion-token datasets | Statistical arguments that failed at small scale may now hold |
| Regulation | EU AI Act, GDPR | Creates demand for compliant alternatives |
| Tooling | New frameworks, APIs | Reduces implementation barrier for complex methods |
| Failure | High-profile system failures | Exposes gaps in existing approaches |
| Cultural | New user behaviors | Shifts what problems matter most |
Workflow:
- Pick a well-known negative result or abandoned approach (3-10 years old)
- List the assumptions that led to its rejection
- For each assumption, ask: Is this still true today?
- If any assumption has been invalidated →