A General One-dimensional Tracer Transport Equation via the Dual Approach: Direct Integration of the Three-dimensional River Model

One-dimensional advection–dispersion formulations are widely used to model solute fate in rivers, yet they typically rely on restrictive cross-sectional averaging assumptions. Building on the dual approach, which formalizes dimensional reduction without ad hoc closures, we derive a general one-dimensional tracer transport equation by directly integrating the three-dimensional tracer conservation law for open-channel flow. The resulting formulation preserves the effects of cross-sectional heterogeneity through rigorously obtained correction terms that account for shear dispersion and transverse exchange, and it clarifies the conditions under which these terms vanish.
We show analytically that the previously proposed one-dimensional equation obtained by combining dual-approach reductions in the horizontal and vertical directions (the “two-horizontal/two-vertical” construction) is a special case of the present derivation. Under standard homogeneity and rapid-mixing limits, our equation reduces to the classical cross-sectional advection–dispersion model, ensuring backward compatibility with established practice. Validation against observed tracer data from a natural river reach demonstrates that the new formulation reproduces concentration evolution and longitudinal spreading more accurately than both the classical one-dimensional model and the combined two-horizontal/two-vertical dual-approach equation. By strengthening the theoretical foundations of dimension-reduced transport and improving empirical fidelity, the proposed equation offers a robust tool for analyzing pollutant dispersion and solute dynamics in fluvial environments and for guiding monitoring and management in rivers with pronounced lateral and vertical structure.

Keywords: classical cross-sectional averaging; dual approach; Huong River; one-dimensional tracer transport equation; three-dimensional tracer transport equation; advection–dispersion; shear dispersion.

DOI https://doi.org/10.55463/issn.1674-2974.52.7.8

O. REYNOLDS, On the dynamical theory of incompressible viscous fluids and the determination of the criterion. Philosophical Transactions of the Royal Society of London, Series A, 186, (1895), 123–164.

J. L. MARTIN, & S. MCCUTCHEON, Hydrodynamics and transport for water quality modeling. CRC Press. https://doi.org/10.1201/9780203751510 (1998).

T. H. NGUYEN, Salinity intrusion in Huong River network and the measure of hydraulic construction. Journal of Science & Technology, Technical Universities, 2, (1992), 17–21.

F. M. WHITE, Fluid mechanics. McGraw-Hill, Inc., 1991.

W. WU, Computation river dynamics. Taylor and Francis/Balkema, 2007.

Y. WATANABE, Dynamics of water surface flows and waves. CRC Press, 2022.

NGUYEN Dong Anh, Dual approach to averaged values of functions. Vietnam Journal of Mechanics, 34(3), (2012a), 211–214.

NGUYEN Dong Anh, Dual approach to averaged values of functions: Advanced formulas. Vietnam Journal of Mechanics, 34(4), (2012b), 321–325.

T. H. NGUYEN, A dual approach to modeling solute transport. Proceedings of the International Conference on Advances in Computational Mechanics, (2017), pp. 821-834.

T. T. TON, T. H. NGUYEN, & D. A. NGUYEN, A dual approach for model construction of two-dimensional horizontal flow. Proceedings of the 10th International Conference on Asian and Pacific Coasts (APAC 2019), Hanoi, Vietnam, September 25–28, (2019), pp. 115–120.

T. H. NGUYEN, A dual approach for modeling two- and one-dimensional solute transport. The International Conference on Modern Mechanics and Applications (ICOMMA2020), December 2–4, Ho Chi Minh City, Vietnam. Lecture Notes in Mechanical Engineering, (2020), pp. 978-981.

T. H. NGUYEN, Building mathematical model of two-dimensional vertical flow by dual approach. Journal of Water Resources Science and Technology, 71, (2022), 109–116.

T. H. NGUYEN, A mathematical model of two-dimensional vertical flow based on the dual approach. Proceedings of the 4th International Conference on Sustainability in Civil Engineering, (2023a), pp. 271–286.

T. H. NGUYEN, Averaging equation of three-dimensional tracer transport by a dual approach. Conference Series: Materials Science and Engineering, 1289, (2023b), 012018. https://doi.org/10.1088/1757-899X/1289/1/012018.

T. H. NGUYEN, Statistical representation of wave by a dual approach. Proceedings of The National Conferences on Fluid Mechanics, 26, (2023c), pp. 313–319.

T. H. NGUYEN, & D. A. Nguyen, Averaging Navier-Stokes equations by a dual approach. International Journal of Computational Methods. https://doi.org/10.1142/S0219876223410062 (2023).

T. H. NGUYEN, Averaging equation of three-dimensional tracer transport by a dual approach. Conference Series: Materials Science and Engineering, 1289, (2023a), 012018. https://doi.org/10.1088/1757-899X/1289/1/012018.

T. H. NGUYEN, H. Q. NGUYEN, T. NGUYEN, New scientific discoveries and inventions based on the similarity principle in the universe. Proceedings of the 10th International New York Conference on Evolving Trends in Interdisciplinary Research & Practices, June 1-3, (2024), pp. 213–223.

NGUYEN T. H., LUONG N. H. P., NGUYEN T. M. L., AND NGUYEN T. P. Calculation of hydrodynamic characteristics by a dual approach. 11th International New York conference on evolving trends in interdisciplinary research & practices, New York, 2025, pp. 579–585.

T. D. NGUYEN, Mathematical modeling of one-dimension of tidal motion and salinity intrusion in River network, PhD Thesis, Hanoi, 1987.