Ideal (inviscid, incompressible) fluid behavior: Which fundamental relationship does an ideal flow strictly obey in continuum mechanics?

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Solve this multiple-choice question and choose the correct option.

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Introduction / Context: An ideal fluid is inviscid (μ = 0) and incompressible. Recognizing which governing equations remain applicable helps in simplifying many hydraulics and aerodynamics problems, particularly when using Bernoulli’s theorem and potential flow theory. Given Data / Assumptions: μ = 0 (no viscous stresses), ρ = constant (incompressible). Continuum hypothesis holds; body forces and pressure act normally. Concept / Approach: All real flows respect conservation laws. For an ideal fluid, the viscous constitutive relation (Newton’s law of viscosity) is irrelevant. However, mass conservation — the continuity equation — must be satisfied in any flow. Momentum conservation (Euler’s equations) also apply, but the question asks what an ideal flow “obeys” distinctively compared with real-fluid constitutive behavior. Step-by-Step Solution: Note that τ = μ dv/dy → 0 for μ = 0; hence Newton’s viscosity law is not the operative relation.Continuity: ∂ρ/∂t + ∇·(ρV) = 0 simplifies to ∇·V = 0 for incompressible ideal flow—this is always valid.Euler/Bernoulli may be derived from momentum conservation under inviscid assumptions, but continuity is universally required. Verification / Alternative check: In potential flow (ideal), velocity field derives from a scalar potential satisfying Laplace’s equation with ∇·V = 0 — a direct expression of continuity. Why Other Options Are Wrong: Newton’s law of viscosity characterizes viscous fluids, not ideal ones. F = m a is true but not a constitutive relation specific to ideal flow; it governs dynamics in general. “Dynamic viscosity law” reiterates viscous behavior. Bernoulli without continuity is incomplete; continuity is essential. Common Pitfalls: Assuming Bernoulli alone characterizes ideal flow; mass conservation still constrains velocity fields and discharge. Final Answer: Continuity equation (mass conservation)

Ideal (inviscid, incompressible) fluid behavior: Which fundamental relationship does an ideal flow strictly obey in continuum mechanics?

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