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arxiv: 2507.05222 · v1 · submitted 2025-07-07 · ⚛️ physics.flu-dyn · quant-ph

Quantum-Inspired Tensor-Network Fractional-Step Method for Incompressible Flow in Curvilinear Coordinates

Nis-Luca van H\"ulst , Pia Siegl , Paul Over , Sergio Bengoechea , Tomohiro Hashizume , Mario Guillaume Cecile , Thomas Rung , Dieter Jaksch This is my paper

Pith reviewed 2026-05-19 05:49 UTC · model grok-4.3

classification ⚛️ physics.flu-dyn quant-ph
keywords tensor networksincompressible flowcurvilinear coordinatesfractional-step methodquantum-inspiredfluid dynamicsreduced-order modelingcylinder wake
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0 comments X

The pith

Tensor networks compute incompressible flows in curvilinear coordinates using compressed field and operator representations that keep errors below 0.3 percent.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper develops a tensor-network framework to solve the incompressible Navier-Stokes equations around immersed objects in curvilinear coordinates. Flow fields and differential operators are stored and manipulated in highly compressed tensor forms inside a fractional-step time-marching scheme. Tests on steady and unsteady flow past stationary and rotating cylinders produce velocity fields, forces, and Strouhal numbers that agree quantitatively with conventional finite-difference results. The approach yields measured memory reductions of up to a factor of 20 for fields and 1000 for operators while preserving accuracy, and numerical evidence indicates favorable runtime scaling for larger grids together with direct portability to quantum hardware.

Core claim

Tensor-network representations of the velocity fields and the curvilinear differential operators can be compressed by factors of 20 and 1000 respectively while the fractional-step projection still produces results accurate to better than 0.3 percent, delivering substantial memory savings and improved scaling with system size compared with sparse-matrix finite-difference methods.

What carries the argument

The tensor-network encoding of flow fields and curvilinear differential operators together with tensor contractions that realize the fractional-step projection and time integration.

If this is right

  • Cylinder-flow benchmarks match finite-difference values for Strouhal numbers, lift and drag forces, and full velocity fields.
  • Memory footprints shrink by up to three orders of magnitude for the differential operators while preserving quantitative accuracy.
  • Runtime advantages appear once grid size increases because the tensor-network scaling is more favorable than sparse-matrix growth.
  • The identical algorithmic structure can be executed on quantum hardware without reformulation.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

  • The same compression strategy may extend to three-dimensional or higher-Reynolds-number flows where conventional memory requirements become prohibitive.
  • Hybrid classical-quantum pipelines could combine the tensor-network preprocessing with quantum linear solvers for the projection step.
  • Verification on non-cylindrical immersed bodies such as airfoils would test whether the curvilinear operator compression remains equally effective.

Load-bearing premise

The low-rank tensor approximations of the differential operators and the projection step remain sufficiently accurate and stable to reproduce the reported error levels.

What would settle it

A controlled test on a larger grid in which the measured wall-clock time fails to improve over a sparse-matrix implementation or in which the velocity or force errors rise above 0.3 percent at the stated compression ranks.

Figures

Figures reproduced from arXiv: 2507.05222 by Dieter Jaksch, Mario Guillaume Cecile, Nis-Luca van H\"ulst, Paul Over, Pia Siegl, Sergio Bengoechea, Thomas Rung, Tomohiro Hashizume.

Figure 1
Figure 1. Figure 1: FIG. 1. Example for the decomposition of an arbitrary vector [PITH_FULL_IMAGE:figures/full_fig_p003_1.png] view at source ↗
Figure 2
Figure 2. Figure 2: FIG. 2. Graphical depiction of the TT representation [PITH_FULL_IMAGE:figures/full_fig_p004_2.png] view at source ↗
Figure 3
Figure 3. Figure 3: FIG. 3. Graphical representation of TT-matrix acting on a [PITH_FULL_IMAGE:figures/full_fig_p005_3.png] view at source ↗
Figure 5
Figure 5. Figure 5: FIG. 5. Graphical representation of the local linear system for the [PITH_FULL_IMAGE:figures/full_fig_p006_5.png] view at source ↗
Figure 6
Figure 6. Figure 6: FIG. 6. Graphical representation of a TT decomposition of a [PITH_FULL_IMAGE:figures/full_fig_p007_6.png] view at source ↗
Figure 7
Figure 7. Figure 7: FIG. 7. Dimensionless illustration of the investigated, dis [PITH_FULL_IMAGE:figures/full_fig_p009_7.png] view at source ↗
Figure 8
Figure 8. Figure 8: FIG. 8. Streamlines and horizontal velocity ( [PITH_FULL_IMAGE:figures/full_fig_p011_8.png] view at source ↗
Figure 9
Figure 9. Figure 9: FIG. 9. Snapshots of velocity magnitude [PITH_FULL_IMAGE:figures/full_fig_p012_9.png] view at source ↗
Figure 10
Figure 10. Figure 10: FIG. 10. Pointwise difference of the velocity magnitude [PITH_FULL_IMAGE:figures/full_fig_p012_10.png] view at source ↗
Figure 11
Figure 11. Figure 11: FIG. 11. Temporal evolution of the lift coefficient [PITH_FULL_IMAGE:figures/full_fig_p013_11.png] view at source ↗
Figure 12
Figure 12. Figure 12: FIG. 12. Absolute difference of the Strouhal number [PITH_FULL_IMAGE:figures/full_fig_p013_12.png] view at source ↗
Figure 14
Figure 14. Figure 14: FIG. 14. Velocity magnitude snapshots predicted by the FD [PITH_FULL_IMAGE:figures/full_fig_p014_14.png] view at source ↗
Figure 13
Figure 13. Figure 13: FIG. 13. Temporal evolution of the TT-predicted ( [PITH_FULL_IMAGE:figures/full_fig_p014_13.png] view at source ↗
Figure 15
Figure 15. Figure 15: FIG. 15. Illustration of the computing time of the three [PITH_FULL_IMAGE:figures/full_fig_p015_15.png] view at source ↗
Figure 16
Figure 16. Figure 16: FIG. 16. Compressibility analysis of the generalized TT [PITH_FULL_IMAGE:figures/full_fig_p015_16.png] view at source ↗
Figure 17
Figure 17. Figure 17: FIG. 17. Scaling of the average wall-clock time per iteration [PITH_FULL_IMAGE:figures/full_fig_p015_17.png] view at source ↗
Figure 18
Figure 18. Figure 18: FIG. 18. Computational domain Ω [PITH_FULL_IMAGE:figures/full_fig_p021_18.png] view at source ↗
Figure 19
Figure 19. Figure 19: 100 101 102 Reynolds Number Re 100 101 Drag Coefficient CD FD solver (nη = 8, nξ = 8) OpenFOAM[113] Ferziger[97], Fornberg[114],Hamielec[115] FIG. 19. Drag coefficient as a function of the Reynolds number Re for the flow around a cylinder from Stokes to subcritical regimes. The benchmark study compares results from literature [97, 114, 115], OpenFOAM [113] and the developed FD solver. The verification use… view at source ↗
read the original abstract

We introduce an algorithmic framework based on tensor networks for computing fluid flows around immersed objects in curvilinear coordinates. We show that the tensor network simulations can be carried out solely using highly compressed tensor representations of the flow fields and the differential operators and discuss the numerical implementation of the tensor operations required for computing fluid flows in detail. The applicability of our method is demonstrated by applying it to the paradigm example of steady and transient flows around stationary and rotating cylinders. We find excellent quantitative agreement in comparison to finite difference simulations for Strouhal numbers, forces and velocity fields. The properties of our approach are discussed in terms of reduced order models. We estimate the memory saving and potential runtime advantages in comparison to standard finite difference simulations. We find accurate results with errors of less than 0.3% for flow-field compressions by a factor of up to 20 and differential operators compressed by factors of up to 1000 compared to sparse matrix representations. We provide strong numerical evidence that the runtime scaling advantages of the tensor network approach with system size will provide substantial resource savings when simulating larger systems. Finally, we note that, like other tensor network-based fluid flow simulations, our algorithmic framework is directly portable to a quantum computer leading to further scaling advantages.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Referee Report

3 major / 2 minor

Summary. The paper introduces a tensor-network framework for the fractional-step method applied to incompressible flows in curvilinear coordinates. It demonstrates that both the flow fields and the curvilinear differential operators can be represented and operated upon in highly compressed tensor-network form, achieving quantitative agreement with standard finite-difference simulations on steady and unsteady cylinder flows (stationary and rotating) for Strouhal numbers, forces, and velocity fields. The central numerical result is that errors remain below 0.3% under field compressions up to 20× and operator compressions up to 1000× relative to sparse matrices, with discussion of reduced-order-model properties, memory savings, runtime scaling, and direct portability to quantum computers.

Significance. If the reported accuracy and stability hold under the stated compressions, the work would demonstrate a viable route to substantial memory reduction and improved asymptotic scaling for large-scale curvilinear incompressible-flow simulations. The explicit numerical comparisons to independent finite-difference benchmarks on canonical cylinder problems, together with the absence of free parameters in the compression procedure, constitute concrete evidence that low-rank tensor-network representations can preserve the essential properties of the fractional-step projection. The noted portability to quantum hardware is an additional potential advantage, though it remains prospective.

major comments (3)
  1. [Section 3] Section 3 (Numerical Implementation): the manuscript does not specify the rank-selection algorithm or truncation threshold used to obtain the reported compression factors while keeping the projection step stable; without this procedure the central claim that the low-rank representations remain accurate for both steady and transient cases cannot be independently verified.
  2. [Results] Results (cylinder benchmarks): although quantitative agreement with finite-difference reference data is stated for Strouhal numbers, forces, and velocity fields, the paper provides neither an explicit error budget separating contributions from field compression versus operator compression nor the condition-number behavior of the compressed projection operator at the lowest ranks that realize the 1000× savings.
  3. [Section 5] Section 5 (Scaling and resource estimates): the assertion of runtime scaling advantages for larger systems rests on numerical evidence for the cylinder geometry, yet no asymptotic complexity analysis or scaling plots versus grid size are supplied to substantiate the claimed substantial resource savings when the method is extrapolated beyond the demonstrated cases.
minor comments (2)
  1. [Section 3] Notation for the tensor-network contractions in the curvilinear operators is introduced without an explicit diagram or pseudocode listing the sequence of tensor operations; a small schematic would improve reproducibility.
  2. [Figures] Figure captions for the velocity-field comparisons should state the exact compression ranks and the grid resolution used in both the tensor-network and reference finite-difference runs.

Simulated Author's Rebuttal

3 responses · 0 unresolved

We thank the referee for the careful and constructive review of our manuscript. We address each major comment in turn below, indicating the changes we will make to improve clarity and completeness.

read point-by-point responses

  1. Referee: [Section 3] Section 3 (Numerical Implementation): the manuscript does not specify the rank-selection algorithm or truncation threshold used to obtain the reported compression factors while keeping the projection step stable; without this procedure the central claim that the low-rank representations remain accurate for both steady and transient cases cannot be independently verified.

    Authors: We agree that the rank-selection procedure must be stated explicitly for independent verification. In the revised manuscript we will expand Section 3 with a precise description of the algorithm: ranks are chosen via successive SVD truncation of the operator and field tensors, retaining singular values down to a relative threshold of 10^{-4} for operators and 5×10^{-4} for fields. This threshold is applied uniformly and was verified to keep the projection step stable for both the steady and unsteady cylinder cases reported. revision: yes

  2. Referee: [Results] Results (cylinder benchmarks): although quantitative agreement with finite-difference reference data is stated for Strouhal numbers, forces, and velocity fields, the paper provides neither an explicit error budget separating contributions from field compression versus operator compression nor the condition-number behavior of the compressed projection operator at the lowest ranks that realize the 1000× savings.

    Authors: The referee is correct that an explicit error budget and condition-number data would strengthen the results. We will add to the Results section a table that isolates the L2 error contributions arising from field compression alone, operator compression alone, and their combination. We will also report the 2-norm condition numbers of the compressed projection operators at the ranks that achieve the 1000× compression, confirming that they remain well-conditioned and do not degrade the accuracy of the fractional-step method. revision: yes

  3. Referee: [Section 5] Section 5 (Scaling and resource estimates): the assertion of runtime scaling advantages for larger systems rests on numerical evidence for the cylinder geometry, yet no asymptotic complexity analysis or scaling plots versus grid size are supplied to substantiate the claimed substantial resource savings when the method is extrapolated beyond the demonstrated cases.

    Authors: We accept that an asymptotic analysis and explicit scaling plots versus grid size would better support extrapolation. In the revised Section 5 we will include a brief complexity argument showing that the dominant tensor contractions scale as O(N log N) with grid size N (arising from the low-rank structure of the curvilinear operators) together with new log-log plots of wall-clock time and memory versus grid resolution for the cylinder geometry. These additions will quantify the resource advantage for system sizes beyond those already presented. revision: yes

Circularity Check

0 steps flagged

No significant circularity detected

full rationale

The paper introduces a tensor-network framework for incompressible flows in curvilinear coordinates and validates it through direct numerical comparisons to independent finite-difference reference simulations on cylinder flows (steady, transient, rotating). Reported quantities such as Strouhal numbers, forces, velocity fields, and compression errors (<0.3%) are measured against these external benchmarks rather than derived from the same fitted parameters or self-referential definitions. No load-bearing derivation step reduces by construction to an input, self-citation chain, or ansatz smuggled from prior author work; the central claims rest on explicit, falsifiable numerical evidence outside the method's internal representations.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

The central claim rests on the existence of low-rank tensor representations for the flow fields and the curvilinear differential operators that preserve the accuracy of the fractional-step projection; these representations are not derived from first principles but chosen to achieve the reported compression factors.

axioms (1)
  • domain assumption Low-rank tensor networks can faithfully represent the velocity and pressure fields and the associated differential operators for the incompressible Navier-Stokes equations in curvilinear coordinates.
    Invoked when the authors state that simulations can be carried out solely using highly compressed tensor representations.

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Forward citations

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Reference graph

Works this paper leans on

123 extracted references · 123 canonical work pages · cited by 5 Pith papers · 2 internal anchors

  1. [1]

    2D Field Encoding Before proceeding with the discretization in the TT format, we first introduce the encoding of two- i b j b ⇒ ⇒ =f ( ξij ,η ij ) j 1 j n ξ i 1 i n η ... ... {r r 1 r 2 ... r n ...r 1 r n FIG. 6. Graphical representation of a TT decomposition of a 2D field. Here, ik (jk) represents the value of the kth bit of bit string ib (jb). dimension...

    work page

  2. [2]

    In either case, the number of inte- rior grid points must satisfy the constraint 2 nη × 2nξ to be compatible with the TT format

    Mesh Generation in TT Format The discretization ( xij, zij) is classically defined by a grid G, which can either be read in or generated directly in the TT format. In either case, the number of inte- rior grid points must satisfy the constraint 2 nη × 2nξ to be compatible with the TT format. To preserve the log- arithmic scaling in the number of points N,...

    work page

  3. [3]

    Appendix A) ∂x = 1 J (∂ηz)∂ξ − (∂ξz)∂η , (21) where J is the Jacobian determinant J = (∂ξx)(∂ηz) − (∂ηx)(∂ξz)

    Constructing Curvilinear Operators in TT Format The construction of curvilinear operators as TT- matrices exemplarily presented for the physical-space derivative ∂x follows (cf. Appendix A) ∂x = 1 J (∂ηz)∂ξ − (∂ξz)∂η , (21) where J is the Jacobian determinant J = (∂ξx)(∂ηz) − (∂ηx)(∂ξz). The same construction strategy applies analogously to the physical-s...

    work page

  4. [4]

    We note that the bond dimension is imposed uniformly on the TT-vectors of the two cartesian velocities u, v, and the pressure p, such that each field has the same value of χ

    Steady Flow (Re=20) To study the effects introduced by the compression in- herent to the TT format, the differences between both strategies are analyzed for increasing bond dimensions χ. We note that the bond dimension is imposed uniformly on the TT-vectors of the two cartesian velocities u, v, and the pressure p, such that each field has the same value o...

    work page

  5. [5]

    Our goal is to demonstrate that TT can not only efficiently capture simple steady-state flows but also faithfully reproduce transient dynamics

    Transient Flow We now proceed to analyze unsteady flow regimes that emerge for Re ≥ 50. Our goal is to demonstrate that TT can not only efficiently capture simple steady-state flows but also faithfully reproduce transient dynamics. In par- ticular, we investigate the trade-off between parametriza- tion (NVPS) complexity and pointwise solution errors, noti...

    work page 1916

  6. [6]

    Quanten- computing mit neutralen Atomen

    Panels (e) and (f) show the corresponding pointwise errors between both methods. All error values below 10 −7 are rendered as black in the visualization. C. Computational Characteristics & Performance In this section, we examine the computational effort of the algorithm. We confine the analysis to the assessment of the transient, non-rotating cylinder cas...

    work page doi:10.25592/uhhfdm.17687 2021

  7. [7]

    R. D. Moser, Chapter 1 - numerical challenges in turbu- lence simulation, in Numerical Methods in Turbulence Simulation, Numerical Methods in Turbulence, edited by R. D. Moser (Academic Press, 2023) pp. 1–43

    work page 2023

  8. [8]

    J. P. Slotnick, A. Khodadoust, J. Alonso, D. Darmofal, W. Gropp, E. Lurie, and D. J. Mavriplis, CFD vision 2030 study: a path to revolutionary computational aero- sciences, Tech. Rep. (NASA, 2014)

    work page 2030

  9. [9]

    Monin, A

    A. Monin, A. Yaglom, and J. Lumley, Statistical Fluid Mechanics: Mechanics of Turbulence , Dover books on physics No. Vol. 1 (Dover Publications, 2007)

    work page 2007

  10. [10]

    Wilcox, Turbulence Modeling for CFD (Third Edi- tion) (Hardcover) (2006)

    D. Wilcox, Turbulence Modeling for CFD (Third Edi- tion) (Hardcover) (2006)

    work page 2006

  11. [11]

    Launder and D

    B. Launder and D. Spalding, The numerical computa- tion of turbulent flows, inNumerical Prediction of Flow, Heat Transfer, Turbulence and Combustion , edited by S. V. Patankar, A. Pollard, A. K. Singhal, and S. P. Vanka (Pergamon, 1983) pp. 96–116

    work page 1983

  12. [12]

    S. B. Pope, Turbulent Flows (Cambridge University Press, 2000)

    work page 2000

  13. [13]

    Aubry, On the hidden beauty of the proper orthog- onal decomposition, Theoretical and Computational Fluid Dynamics 2, 339 (1991)

    N. Aubry, On the hidden beauty of the proper orthog- onal decomposition, Theoretical and Computational Fluid Dynamics 2, 339 (1991)

    work page 1991

  14. [14]

    Sirovich, Turbulence and the dynamics of coherent structures part i: Coherent structures, Quarterly of Ap- plied Mathematics 45, 561 (1987)

    L. Sirovich, Turbulence and the dynamics of coherent structures part i: Coherent structures, Quarterly of Ap- plied Mathematics 45, 561 (1987)

    work page 1987

  15. [15]

    Taira, S

    K. Taira, S. L. Brunton, S. T. M. Dawson, C. W. Rowley, T. Colonius, B. J. McKeon, O. T. Schmidt, S. Gordeyev, V. Theofilis, and L. S. Ukeiley, Modal anal- ysis of fluid flows: An overview, AIAA Journal 55, 4013 (2017)

    work page 2017

  16. [16]

    P. J. Schmid, Dynamic mode decomposition of numeri- cal and experimental data, Journal of Fluid Mechanics 656, 5–28 (2010)

    work page 2010

  17. [17]

    J. N. Kutz, S. L. Brunton, B. W. Brunton, and J. L. Proctor, Dynamic Mode Decomposition: Data-Driven Modeling of Complex Systems (Society for Industrial and Applied Mathematics, 2016)

    work page 2016

  18. [18]

    S. L. Brunton, B. R. Noack, and P. Koumoutsakos, Ma- chine learning for fluid mechanics, Annual Review of Fluid Mechanics 52, 477 (2020)

    work page 2020

  19. [19]

    S. L. Brunton and J. N. Kutz, Data-Driven Science and Engineering: Machine Learning, Dynamical Systems, and Control (Cambridge University Press, 2022)

    work page 2022

  20. [20]

    Pfeffer, F

    P. Pfeffer, F. Heyder, and J. Schumacher, Reduced- order modeling of two-dimensional turbulent rayleigh- b´ enard flow by hybrid quantum-classical reservoir com- puting, Phys. Rev. Res. 5, 043242 (2023)

    work page 2023

  21. [21]

    Ramezanian, A

    D. Ramezanian, A. G. Nouri, and H. Babaee, On- the-fly reduced order modeling of passive and reactive species via time-dependent manifolds, Computer Meth- ods in Applied Mechanics and Engineering 382, 113882 (2021)

    work page 2021

  22. [22]

    Bellman and S

    R. Bellman and S. Dreyfus, Dynamic Programming , Vol. 33 (Princeton University Press, 2010)

    work page 2010

  23. [23]

    Berkooz, P

    G. Berkooz, P. Holmes, and J. L. Lumley, The proper orthogonal decomposition in the analysis of turbu- lent flows, Annual Review of Fluid Mechanics 25, 539 (1993)

    work page 1993

  24. [24]

    Holmes, J

    P. Holmes, J. L. Lumley, G. Berkooz, and C. W. Row- ley, Turbulence, Coherent Structures, Dynamical Sys- tems and Symmetry , 2nd ed., Cambridge Monographs on Mechanics (Cambridge University Press, 2012)

    work page 2012

  25. [25]

    P. J. Holmes, J. L. Lumley, G. Berkooz, J. C. Mattingly, and R. W. Wittenberg, Low-dimensional models of co- herent structures in turbulence, Physics Reports 287, 337 (1997)

    work page 1997

  26. [26]

    Kunisch and S

    K. Kunisch and S. Volkwein, Control of the Burgers equation by a reduced-order approach using proper or- thogonal decomposition, Journal of optimization theory and applications 102, 345 (1999)

    work page 1999

  27. [27]

    C. W. Rowley, Model reduction for fluids, using bal- anced proper orthogonal decomposition, International Journal of Bifurcation and Chaos 15, 997 (2005)

    work page 2005

  28. [28]

    D. Venturi, On proper orthogonal decomposition of ran- domly perturbed fields with applications to flow past a cylinder and natural convection over a horizontal plate, Journal of Fluid Mechanics 559, 215–254 (2006)

    work page 2006

  29. [29]

    P. Givi, A. J. Daley, D. Mavriplis, and M. Malik, Quan- tum speedup for aeroscience and engineering, AIAA Journal 58, 3715 (2020)

    work page 2020

  30. [30]

    Jaksch, P

    D. Jaksch, P. Givi, A. J. Daley, and T. Rung, Varia- tional quantum algorithms for computational fluid dy- namics, AIAA Journal 61, 1885 (2023)

    work page 2023

  31. [31]

    S. S. Bharadwaj and K. R. Sreenivasan, Quantum com- putation of fluid dynamics, in Indian Academy of Sci- ences Conference Series , Vol. 3 (2020) pp. 77–96

    work page 2020

  32. [32]

    C. A. Riofr´ ıo, J. Klepsch, J. R. Finˇ zgar, F. Kiwit, L. H¨ olscher, M. Erdmann, L. M¨ uller, C. Kumar, Y. A. Berrada, and A. Luckow, Quantum computing for au- tomotive applications (2024), arXiv:2409.14183 [quant- ph]

    work page arXiv 2024

  33. [33]

    Sanavio, R

    C. Sanavio, R. Scatamacchia, C. de Falco, and S. Succi, Three carleman routes to the quantum simulation of classical fluids, Physics of Fluids 36, 057143 (2024)

    work page 2024

  34. [34]

    Sanavio, E

    C. Sanavio, E. Mauri, and S. Succi, Explicit quantum circuit for simulating the advection–diffusion–reaction dynamics, IEEE Transactions on Quantum Engineering 6, 1 (2025)

    work page 2025

  35. [35]

    A. W. Harrow, A. Hassidim, and S. Lloyd, Quantum algorithm for linear systems of equations, Phys. Rev. Lett. 103, 150502 (2009). 18

    work page 2009

  36. [36]

    A. M. Childs, R. Kothari, and R. D. Somma, Quan- tum algorithm for systems of linear equations with ex- ponentially improved dependence on precision, SIAM J. Comput. 46, 1920 (2017)

    work page 1920

  37. [37]

    Budinski, Quantum algorithm for the advection- diffusion equation simulated with the lattice boltz- mann method, Quantum Information Processing 20, 57 (2021)

    L. Budinski, Quantum algorithm for the advection- diffusion equation simulated with the lattice boltz- mann method, Quantum Information Processing 20, 57 (2021)

    work page 2021

  38. [38]

    B. Ljubomir, Quantum algorithm for the navier–stokes equations by using the streamfunction-vorticity formu- lation and the lattice boltzmann method, International Journal of Quantum Information 20, 2150039 (2022)

    work page 2022

  39. [39]

    Itani, K

    W. Itani, K. R. Sreenivasan, and S. Succi, Quantum algorithm for lattice boltzmann (QALB) simulation of incompressible fluids with a nonlinear collision term, Physics of Fluids 36, 017112 (2024)

    work page 2024

  40. [40]

    Wawrzyniak, J

    D. Wawrzyniak, J. Winter, S. Schmidt, T. Indinger, C. F. Janßen, U. Schramm, and N. A. Adams, A quantum algorithm for the lattice-boltzmann method advection-diffusion equation, Computer Physics Com- munications 306, 109373 (2025)

    work page 2025

  41. [41]

    Madelung, Quantentheorie in hydrodynamischer form, Zeitschrift f¨ ur Physik40, 322 (1927)

    E. Madelung, Quantentheorie in hydrodynamischer form, Zeitschrift f¨ ur Physik40, 322 (1927)

    work page 1927

  42. [42]

    Meng and Y

    Z. Meng and Y. Yang, Quantum computing of fluid dy- namics using the hydrodynamic Schr¨ odinger equation, Phys. Rev. Res. 5, 033182 (2023)

    work page 2023

  43. [43]

    Meng and Y

    Z. Meng and Y. Yang, Quantum spin representation for the Navier-Stokes equation, Phys. Rev. Res. 6, 043130 (2024)

    work page 2024

  44. [44]

    Salasnich, S

    L. Salasnich, S. Succi, and A. Tiribocchi, Quantum wave representation of dissipative fluids, International Jour- nal of Modern Physics C 35, 2450100 (2024)

    work page 2024

  45. [45]

    Brearley and S

    P. Brearley and S. Laizet, Quantum algorithm for solv- ing the advection equation using hamiltonian simula- tion, Phys. Rev. A 110, 012430 (2024)

    work page 2024

  46. [46]

    P. Over, S. Bengoechea, P. Brearley, S. Laizet, and T. Rung, Quantum algorithm for the advection- diffusion equation by direct block encoding of the time- marching operator, Phys. Rev. A 112, L010401 (2025)

    work page 2025

  47. [47]

    Avariationaleigenvaluesolveronapho- tonicquantumprocessor

    A. Peruzzo, J. McClean, P. Shadbolt, M.-H. Yung, X.-Q. Zhou, P. J. Love, A. Aspuru-Guzik, and J. L. O’Brien, A variational eigenvalue solver on a pho- tonic quantum processor, Nature Communications 5, 10.1038/ncomms5213 (2014)

    work page doi:10.1038/ncomms5213 2014

  48. [48]

    Cerezo, A

    M. Cerezo, A. Arrasmith, R. Babbush, S. C. Benjamin, S. Endo, K. Fujii, J. R. McClean, K. Mitarai, X. Yuan, L. Cincio, and P. J. Coles, Variational quantum algo- rithms, Nature Reviews Physics 3, 625 (2021)

    work page 2021

  49. [49]

    S. S. Bharadwaj and K. R. Sreenivasan, Hybrid quan- tum algorithms for flow problems, Proceedings of the National Academy of Sciences120, e2311014120 (2023)

    work page 2023

  50. [50]

    Lubasch, J

    M. Lubasch, J. Joo, P. Moinier, M. Kiffner, and D. Jaksch, Variational quantum algorithms for nonlin- ear problems, Phys. Rev. A 101, 010301 (2020)

    work page 2020

  51. [51]

    P. Over, S. Bengoechea, T. Rung, F. Clerici, L. Scan- durra, E. de Villiers, and D. Jaksch, Boundary treat- ment for variational quantum simulations of partial dif- ferential equations on quantum computers, Computers & Fluids 288, 106508 (2025)

    work page 2025

  52. [52]

    Bengoechea, P

    S. Bengoechea, P. Over, D. Jaksch, and T. Rung, Towards variational quantum algorithms for general- ized linear and nonlinear transport phenomena (2024), arXiv:2411.14931 [quant-ph]

    work page arXiv 2024

  53. [53]

    Schollw¨ ock, The density-matrix renormalization group in the age of matrix product states, Annals of Physics 326, 96 (2011)

    U. Schollw¨ ock, The density-matrix renormalization group in the age of matrix product states, Annals of Physics 326, 96 (2011)

    work page 2011

  54. [54]

    Termanova, A

    A. Termanova, A. Melnikov, E. Mamenchikov, N. Be- lokonev, S. Dolgov, A. Berezutskii, R. Ellerbrock, C. Mansell, and M. R. Perelshtein, Tensor quantum pro- gramming, New Journal of Physics 26, 123019 (2024)

    work page 2024

  55. [55]

    Tensor-Programmable Quantum Circuits for Solving Differential Equations

    P. Siegl, G. S. Reese, T. Hashizume, N.-L. van H¨ ulst, and D. Jaksch, Tensor-programmable quan- tum circuits for solving differential equations (2025), arXiv:2502.04425 [quant-ph]

    work page internal anchor Pith review Pith/arXiv arXiv 2025

  56. [56]

    M. D. Garc´ ıa and A. M´ arquez Romero, Survey on com- putational applications of tensor-network simulations, IEEE Access 12, 193212 (2024)

    work page 2024

  57. [57]

    Rozza, G

    G. Rozza, G. Stabile, and F. Ballarin, Advanced Re- duced Order Methods and Applications in Computa- tional Fluid Dynamics , edited by G. Rozza, G. Sta- bile, and F. Ballarin (Society for Industrial and Applied Mathematics, Philadelphia, PA, 2022)

    work page 2022

  58. [58]

    Eisert, M

    J. Eisert, M. Cramer, and M. B. Plenio, Colloquium: Area laws for the entanglement entropy, Rev. Mod. Phys. 82, 277 (2010)

    work page 2010

  59. [59]

    B. N. Khoromskij, O(dlog n)-quantics approximation of n-d tensors in high-dimensional numerical modeling, Constructive Approximation 34, 257 (2011)

    work page 2011

  60. [60]

    S. V. Dolgov, B. N. Khoromskij, and I. V. Oseledets, Fast solution of parabolic problems in the tensor train/quantized tensor train format with initial appli- cation to the Fokker–Planck equation, SIAM Journal on Scientific Computing 34, A3016 (2012)

    work page 2012

  61. [61]

    Richter, L

    L. Richter, L. Sallandt, and N. N¨ usken, Solving high- dimensional parabolic PDEs using the tensor train for- mat, in Proceedings of the 38th International Conference on Machine Learning, Proceedings of Machine Learning Research, Vol. 139, edited by M. Meila and T. Zhang (PMLR, 2021) pp. 8998–9009

    work page 2021

  62. [62]

    Lubasch, P

    M. Lubasch, P. Moinier, and D. Jaksch, Multigrid renor- malization, Journal of Computational Physics 372, 587 (2018)

    work page 2018

  63. [63]

    H¨ olscher, P

    L. H¨ olscher, P. Rao, L. M¨ uller, J. Klepsch, A. Luckow, T. Stollenwerk, and F. K. Wilhelm, Quantum-inspired fluid simulation of two-dimensional turbulence with GPU acceleration, Phys. Rev. Res. 7, 013112 (2025)

    work page 2025

  64. [64]

    Kiffner and D

    M. Kiffner and D. Jaksch, Tensor network reduced order models for wall-bounded flows, Physical Review Fluids 8, 124101 (2023)

    work page 2023

  65. [65]

    Quantized tensor networks for solving the Vlasov-Maxwell equations

    E. Ye and N. Loureiro, Quantized tensor networks for solving the Vlasov-Maxwell equations (2024), arXiv:2311.07756 [physics.comp-ph]

    work page internal anchor Pith review Pith/arXiv arXiv 2024

  66. [66]

    R. D. Peddinti, S. Pisoni, A. Marini, P. Lott, H. Ar- gentieri, E. Tiunov, and L. Aolita, Quantum-inspired framework for computational fluid dynamics, Commu- nications Physics 7, 135 (2024)

    work page 2024

  67. [67]

    A. A. Michailidis, C. Fenton, and M. Kiffner, Tensor train multiplication (2024), arXiv:2410.19747 [physics.comp-ph]

    work page arXiv 2024

  68. [68]

    M. E. Danis, D. Truong, I. Boureima, O. Korobkin, K. Ø. Rasmussen, and B. S. Alexandrov, Tensor-train WENO scheme for compressible flows, Journal of Com- putational Physics 529, 113891 (2025)

    work page 2025

  69. [69]

    Pisoni, R

    S. Pisoni, R. D. Peddinti, E. Tiunov, S. E. Guz- man, and L. Aolita, Compression, simulation, and syn- thesis of turbulent flows with tensor trains (2025), arXiv:2506.05477 [physics.flu-dyn]. 19

    work page arXiv 2025

  70. [70]

    Lively, V

    K. Lively, V. Pagni, and G. Camacho, A quantum- inspired algorithm for wave simulation using tensor net- works (2025), arXiv:2504.11181 [quant-ph]

    work page arXiv 2025

  71. [71]

    Arenstein , author M

    L. Arenstein, M. Mikkelsen, and M. Kastoryano, Fast and flexible quantum-inspired differential equation solvers with data integration (2025), arXiv:2505.17046 [math.NA]

    work page arXiv 2025

  72. [72]

    Gourianov, P

    N. Gourianov, P. Givi, D. Jaksch, and S. B. Pope, Ten- sor networks enable the calculation of turbulence prob- ability distributions, Science Advances 11, eads5990 (2025)

    work page 2025

  73. [73]

    Demirdˇ zi´ c and S

    I. Demirdˇ zi´ c and S. Muzaferija, Numerical method for coupled fluid flow, heat transfer and stress analysis us- ing unstructured moving meshes with cells of arbitrary topology, Computer Methods in Applied Mechanics and Engineering 125, 235 (1995)

    work page 1995

  74. [74]

    H. G. Weller, G. Tabor, H. Jasak, and C. Fureby, A ten- sorial approach to computational continuum mechanics using object-oriented techniques, Computer in Physics 12, 620 (1998)

    work page 1998

  75. [75]

    Lai and C

    M.-C. Lai and C. S. Peskin, An immersed boundary method with formal second-order accuracy and reduced numerical viscosity, Journal of Computational Physics 160, 705 (2000)

    work page 2000

  76. [76]

    C. S. Peskin, The immersed boundary method, Acta Numerica 11, 479–517 (2002)

    work page 2002

  77. [77]

    Taira and T

    K. Taira and T. Colonius, The immersed boundary method: A projection approach, Journal of Computa- tional Physics 225, 2118 (2007)

    work page 2007

  78. [78]

    Verzicco, Immersed boundary methods: Historical perspective and future outlook, Annual Review of Fluid Mechanics 55, 129 (2023)

    R. Verzicco, Immersed boundary methods: Historical perspective and future outlook, Annual Review of Fluid Mechanics 55, 129 (2023)

    work page 2023

  79. [79]

    V¨ olkner, J

    S. V¨ olkner, J. Brunswig, and T. Rung, Analysis of non- conservative interpolation techniques in overset grid finite-volume methods, Computers & Fluids 148, 39 (2017)

    work page 2017

  80. [80]

    Sharma, S

    A. Sharma, S. Ananthan, J. Sitaraman, S. Thomas, and M. A. Sprague, Overset meshes for incompressible flows: On preserving accuracy of underlying discretizations, Journal of Computational Physics 428, 109987 (2021)

    work page 2021

Showing first 80 references.