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| Format: | Preprint |
| Published: |
2026
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| Online Access: | https://arxiv.org/abs/2604.22073 |
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| _version_ | 1866914503507050496 |
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| author | Jenssen, Helge Kristian |
| author_facet | Jenssen, Helge Kristian |
| contents | We consider the compressible Euler system for ideal gas flow in the absence of
any forces except the internal thermodynamic pressure. In this setting, and in dimensions
higher 1, it is known that wave-focusing can drive Euler solutions to amplitude blowup
in finite time from bounded initial data. In the known cases (self-similar, radial flows
\cites{gud,hun_60,jt3,laz,mrrs1,jls})
the primary flow variables are standard functions at time of blowup.
It is natural to ask if the Euler system admits even more singular behavior, and
specifically whether accumulation of mass, i.e., the appearance of a Dirac delta
in the density field, is possible.
We consider the class of radial affine motions \cites{mcvittie,sed, kell,sid_2014}
which are conveniently obtained via a Lagrangian formulation.
This class does include examples of cumulative behavior, and we observe that
there are two distinct mechanisms for accumulation, due to inertial effects or adverse
pressure gradients, respectively. However, we show that all affine cumulative solutions
necessarily exhibit unphysical behavior due to initially unbounded velocity and/or
acceleration in the far-field.
We also analyze the behavior of characteristics in
cumulative flows and consider concrete examples, including a class of 1-dimensional,
non-affine flows. Finally, we discuss the possibility of modifying the
known examples to obtain physically acceptable gas flows displaying
accumulation. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2604_22073 |
| institution | arXiv |
| publishDate | 2026 |
| record_format | arxiv |
| spellingShingle | Cumulative Euler flows Jenssen, Helge Kristian Analysis of PDEs 76N15, 35L65 We consider the compressible Euler system for ideal gas flow in the absence of any forces except the internal thermodynamic pressure. In this setting, and in dimensions higher 1, it is known that wave-focusing can drive Euler solutions to amplitude blowup in finite time from bounded initial data. In the known cases (self-similar, radial flows \cites{gud,hun_60,jt3,laz,mrrs1,jls}) the primary flow variables are standard functions at time of blowup. It is natural to ask if the Euler system admits even more singular behavior, and specifically whether accumulation of mass, i.e., the appearance of a Dirac delta in the density field, is possible. We consider the class of radial affine motions \cites{mcvittie,sed, kell,sid_2014} which are conveniently obtained via a Lagrangian formulation. This class does include examples of cumulative behavior, and we observe that there are two distinct mechanisms for accumulation, due to inertial effects or adverse pressure gradients, respectively. However, we show that all affine cumulative solutions necessarily exhibit unphysical behavior due to initially unbounded velocity and/or acceleration in the far-field. We also analyze the behavior of characteristics in cumulative flows and consider concrete examples, including a class of 1-dimensional, non-affine flows. Finally, we discuss the possibility of modifying the known examples to obtain physically acceptable gas flows displaying accumulation. |
| title | Cumulative Euler flows |
| topic | Analysis of PDEs 76N15, 35L65 |
| url | https://arxiv.org/abs/2604.22073 |