The computation for the curl of the dual basis vectors ( $\nabla \times e^a$ ) in both cylindrical and spherical coordinates yields a null vector ( 0 ) in every case. This fundamental result stems from the general tensorial expression for the curl, which is proportional to the partial derivative of the covariant components of the vector, $\partial_b v_d$. Since the covariant components of the dual basis vector $e^a$ are given by the Kronecker delta, $v_d=\left(e^a\right)_d=\delta_d^a$, these components are constants (i.e., independent of the spatial coordinates). Consequently, their partial derivative is zero, meaning $\nabla \times e^a=0$. This result is further verified when applying the physical component formula, where the term being differentiated, $h_c \tilde{v}_c$, also simplifies to the constant $\delta_c^a$, confirming that all components of the curl are zero in both coordinate systems.

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✍️Mathematical Proof

$\complement\cdots$Counselor

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1. General Result for Dual Basis Curl: The curl of a dual basis vector $\left(\nabla \times e^a\right)$ in any orthogonal curvilinear coordinate system is always zero.

2. Reasoning from General Curl Expression: Using the general expression for the contravariant components of the curl, $(\nabla \times v)^c=\frac{1}{\sqrt{g}} \varepsilon^{c a b} \partial_a v_b$, and noting that the covariant components of $e^a$ are $v_b=\left(e^a\right)_b=\delta_b^a$, the partial derivative term $\partial_a \delta_b^a$ is zero because $\delta_b^a$ is constant.

3. Result in Specific Coordinate Systems: Consequently, the physical components of the curl of the dual basis are all zero in both:

   • Cylindrical Coordinates: $\left(\nabla \times e^\rho\right)_c=0,\left(\nabla \times e^\phi\right)_c=0,\left(\nabla \times e^z\right)_c=0$.
   • Spherical Coordinates: $\left(\nabla \times e^r\right)_c=0,\left(\nabla \times e^\theta\right)_c=0,\left(\nabla \times e^\phi\right)_c=0$.

4. Verification with known formula: The result is confirmed by using the physical component expression. The physical components of $e^a$ are $\tilde{v}_c=\left(e^a\right)_c=\frac{1}{h_c} \delta_c^a$. The term being differentiated, $h_c \tilde{v}_c$, simplifies to $\delta_c^a$, whose derivative is zero.

   $$ \partial_b\left(h_c \tilde{v}_c\right)=\partial_b\left(\delta_c^a\right)=0 $$

   This mathematically validates the zero result in the physical component framework as well.

✍️Mathematical Proof

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1. Derivation of Tensor Transformation Properties for Mixed Tensors
2. The Polar Tensor Basis in Cartesian Form
3. Verifying the Rank Two Zero Tensor
4. Tensor Analysis of Electric Susceptibility in Anisotropic Media
5. Analysis of Ohm's Law in an Anisotropic Medium
6. Verifying Tensor Transformations
7. Proof of Coordinate Independence of Tensor Contraction
8. Proof of a Tensor's Invariance Property
9. Proving Symmetry of a Rank-2 Tensor
10. Tensor Symmetrization and Anti-Symmetrization Properties
11. Symmetric and Antisymmetric Tensor Contractions
12. The Uniqueness of the Zero Tensor under Specific Symmetry Constraints
13. Counting Independent Tensor Components Based on Symmetry
14. Transformation of the Inverse Metric Tensor
15. Finding the Covariant Components of a Magnetic Field
16. Covariant Nature of the Gradient
17. Christoffel Symbol Transformation Rule Derivation
18. Contraction of the Christoffel Symbols and the Metric Determinant
19. Divergence of an Antisymmetric Tensor in Terms of the Metric Determinant
20. Calculation of the Metric Tensor and Christoffel Symbols in Spherical Coordinates
21. Christoffel Symbols for Cylindrical Coordinates
22. Finding Arc Length and Curve Length in Spherical Coordinates
23. Solving for Metric Tensors and Christoffel Symbols
24. Metric Tensor and Line Element in Non-Orthogonal Coordinates
25. Tensor vs. Non-Tensor Transformation of Derivatives
26. Verification of Covariant Derivative Identities
27. Divergence in Spherical Coordinates Derivation and Verification
28. Laplace Operator Derivation and Verification in Cylindrical Coordinates
29. Divergence of Tangent Basis Vectors in Curvilinear Coordinates
30. Derivation of the Laplacian Operator in General Curvilinear Coordinates
31. Verification of Tensor Density Operations
32. Verification of the Product Rule for Jacobian Determinants and Tensor Density Transformation
33. Metric Determinant and Cross Product in Scaled Coordinates
34. Vanishing Divergence of the Levi-Civita Tensor
35. Curl and Vector Cross-Product Identity in General Coordinates
36. Curl of the Dual Basis in Cylindrical and Spherical Coordinates

🧄Proof and Derivation-1

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