Milankovitch theory "as an initial value problem": Implications of the long memory of ice advection.
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| Title: | Milankovitch theory "as an initial value problem": Implications of the long memory of ice advection. |
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| Authors: | Verbitsky, Mikhail Y.1,2 (AUTHOR) verbitskys@gmail.com, Volobuev, Dmitry3 (AUTHOR) |
| Source: | Earth System Dynamics. 2025, Vol. 16 Issue 6, p1989-2002. 14p. |
| Subjects: | Milankovitch cycles, Initial value problems, Atmospheric models, Earth system science, Pleistocene Epoch, Glacial drift |
| Abstract: | We describe a so far unrecognized physical phenomenon of orbital forcing modifying the terrestrial physics in such a way that instead of erasing the memory of the initial conditions this memory is extended and the initial values become major governing parameters. Specifically: The dynamics of large ice sheets is fundamentally defined by the advection of mass and temperature. The timescale of these processes is critically dependent on the surface mass balance. Because of the ice-climate system's nonlinearity, its response to the orbital forcing in terms of the engagement of negative and positive feedbacks is not symmetrical. This asymmetry may reduce the effective mass influx, and the resultant advection timescale may become longer, which is equivalent to the system having a longer memory of its initial conditions. In this case the Milankovitch theory becomes an initial value problem: Depending on the initial conditions, for the same orbital forcing and for the same balance between terrestrial positive and negative feedbacks, the historical glacial rhythmicity could have been dominated either by the eccentricity period of ∼100 kyr, or by the doubled obliquity period of ∼80 kyr, or by a combination of both. In fact, empirical records demonstrate that the dominant period of the Late Pleistocene ice ages evolved from a ∼80 to ∼100 kyr rhythmicity. The quantitative similarity of this dominant-period trajectory and the one, made by the long-memory model, suggests that the records of the Late Pleistocene glacial rhythmicity could have been produced by a long-memory initial-value-dependent climate system, or, in other words, the slopes in empirical dominant-period trajectories are signatures of a long memory. The scaling law of the dominant-period trajectory provides a theoretical insight into the discovered phenomenon. It reveals that this trajectory is dependent on the memory duration that is sensitive to initial conditions. The sensitivity of the memory duration to the initial values emerges as the result of the system's incomplete similarity in two similarity parameters colliding into one conglomerate similarity parameter that is the ratio of the orbitally modified advection timescale and the orbital period. The critical dependence of this similarity parameter on poorly defined accumulation-minus-ablation mass balance as well as its dependence on the initial values makes ice ages fundamentally difficult to predict. For the same reason, the disambiguation of paleo-records is extremely challenging. The quasi-eccentricity periods produced by the long-memory system in response to pure obliquity forcing make a remarkable example of this challenge because in the time series they may be naively attributed to the eccentricity modulated precession forcing. The long-memory relaxation time series may have abrupt dominant-periodicity transitions (e.g., from ∼40 to 80 kyr) produced without any changes of parameters. This observation implies that the middle-Pleistocene transition may be a manifestation of the terrestrial long-memory response to the orbital forcing. [ABSTRACT FROM AUTHOR] |
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| Database: | Engineering Source |
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| Abstract: | We describe a so far unrecognized physical phenomenon of orbital forcing modifying the terrestrial physics in such a way that instead of erasing the memory of the initial conditions this memory is extended and the initial values become major governing parameters. Specifically: The dynamics of large ice sheets is fundamentally defined by the advection of mass and temperature. The timescale of these processes is critically dependent on the surface mass balance. Because of the ice-climate system's nonlinearity, its response to the orbital forcing in terms of the engagement of negative and positive feedbacks is not symmetrical. This asymmetry may reduce the effective mass influx, and the resultant advection timescale may become longer, which is equivalent to the system having a longer memory of its initial conditions. In this case the Milankovitch theory becomes an initial value problem: Depending on the initial conditions, for the same orbital forcing and for the same balance between terrestrial positive and negative feedbacks, the historical glacial rhythmicity could have been dominated either by the eccentricity period of ∼100 kyr, or by the doubled obliquity period of ∼80 kyr, or by a combination of both. In fact, empirical records demonstrate that the dominant period of the Late Pleistocene ice ages evolved from a ∼80 to ∼100 kyr rhythmicity. The quantitative similarity of this dominant-period trajectory and the one, made by the long-memory model, suggests that the records of the Late Pleistocene glacial rhythmicity could have been produced by a long-memory initial-value-dependent climate system, or, in other words, the slopes in empirical dominant-period trajectories are signatures of a long memory. The scaling law of the dominant-period trajectory provides a theoretical insight into the discovered phenomenon. It reveals that this trajectory is dependent on the memory duration that is sensitive to initial conditions. The sensitivity of the memory duration to the initial values emerges as the result of the system's incomplete similarity in two similarity parameters colliding into one conglomerate similarity parameter that is the ratio of the orbitally modified advection timescale and the orbital period. The critical dependence of this similarity parameter on poorly defined accumulation-minus-ablation mass balance as well as its dependence on the initial values makes ice ages fundamentally difficult to predict. For the same reason, the disambiguation of paleo-records is extremely challenging. The quasi-eccentricity periods produced by the long-memory system in response to pure obliquity forcing make a remarkable example of this challenge because in the time series they may be naively attributed to the eccentricity modulated precession forcing. The long-memory relaxation time series may have abrupt dominant-periodicity transitions (e.g., from ∼40 to 80 kyr) produced without any changes of parameters. This observation implies that the middle-Pleistocene transition may be a manifestation of the terrestrial long-memory response to the orbital forcing. [ABSTRACT FROM AUTHOR] |
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| ISSN: | 21904979 |
| DOI: | 10.5194/esd-16-1989-2025 |