Sign singularity of the local energy transfer in space plasma turbulence

Luca Sorriso-Valvo; Gaetano De Vita; Federico Fraternale; Alexandre Gurchumelia; Silvia Perri; Giuseppina Nigro; Filomena Catapano; Alessandro Retinò; Christopher H. Chen; Emiliya Yordanova; Oreste Pezzi; Khatuna Chargazia; Oleg Kharshiladze; Diana Kvaratskhelia; Christian L. Vasconez; Olivier Le Conte; Barbara Giles; Thomas E. Moore; Roy B. Torbert; Jim L. Burch

doi:10.3389/fphy.2019.00108

Sign singularity of the local energy transfer in space plasma turbulence

Luca Sorriso-Valvo
, Gaetano De Vita
, Federico Fraternale
, Alexandre Gurchumelia
, Silvia Perri
, Giuseppina Nigro
, Filomena Catapano
, Alessandro Retinò
, Christopher H. Chen
, Emiliya Yordanova
, Oreste Pezzi
, Khatuna Chargazia
, Oleg Kharshiladze
, Diana Kvaratskhelia
, Christian L. Vasconez
, Olivier Le Conte
, Barbara Giles
, Thomas E. Moore
, Roy B. Torbert
, Jim L. Burch

Research output: Contribution to journal › Article › peer-review

Abstract

In weakly collisional space plasmas, the turbulent cascade provides most of the energy that is dissipated at small scales by various kinetic processes. Understanding the characteristics of such dissipative mechanisms requires the accurate knowledge of the fluctuations that make energy available for conversion at small scales, as different dissipation processes are triggered by fluctuations of a different nature. The scaling properties of different energy channels are estimated here using a proxy of the local energy transfer, based on the third-order moment scaling law for magnetohydrodynamic turbulence. In particular, the sign-singularity analysis was used to explore the scaling properties of the alternating positive-negative energy fluxes, thus providing information on the structure and topology of such fluxes for each of the different type of fluctuations. The results show the highly complex geometrical nature of the flux, and that the local contributions associated with energy and cross-helicity nonlinear transfer have similar scaling properties. Consequently, the fractal properties of current and vorticity structures are similar to those of the Alfv\'enic fluctuations.

Original language	English
Article number	93
Journal	Frontiers in Physics
Volume	7
Issue number	JULY
DOIs	https://doi.org/10.3389/fphy.2019.00108
Publication status	Published - 1 Jul 2019
Externally published	Yes

Keywords

Dissipation
Magnetosphere
Singularity
Space plasmas
Turbulence

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10.3389/fphy.2019.00108

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Sorriso-Valvo, L., De Vita, G., Fraternale, F., Gurchumelia, A., Perri, S., Nigro, G., Catapano, F., Retinò, A., Chen, C. H., Yordanova, E., Pezzi, O., Chargazia, K., Kharshiladze, O., Kvaratskhelia, D., Vasconez, C. L., Le Conte, O., Giles, B., Moore, T. E., Torbert, R. B., & Burch, J. L. (2019). Sign singularity of the local energy transfer in space plasma turbulence. Frontiers in Physics, 7(JULY), Article 93. https://doi.org/10.3389/fphy.2019.00108

@article{63090350c2814cb4b3f92993f1c759aa,

title = "Sign singularity of the local energy transfer in space plasma turbulence",

abstract = "In weakly collisional space plasmas, the turbulent cascade provides most of the energy that is dissipated at small scales by various kinetic processes. Understanding the characteristics of such dissipative mechanisms requires the accurate knowledge of the fluctuations that make energy available for conversion at small scales, as different dissipation processes are triggered by fluctuations of a different nature. The scaling properties of different energy channels are estimated here using a proxy of the local energy transfer, based on the third-order moment scaling law for magnetohydrodynamic turbulence. In particular, the sign-singularity analysis was used to explore the scaling properties of the alternating positive-negative energy fluxes, thus providing information on the structure and topology of such fluxes for each of the different type of fluctuations. The results show the highly complex geometrical nature of the flux, and that the local contributions associated with energy and cross-helicity nonlinear transfer have similar scaling properties. Consequently, the fractal properties of current and vorticity structures are similar to those of the Alfv\textbackslash{}'enic fluctuations.",

keywords = "Dissipation, Magnetosphere, Singularity, Space plasmas, Turbulence",

author = "Luca Sorriso-Valvo and \{De Vita\}, Gaetano and Federico Fraternale and Alexandre Gurchumelia and Silvia Perri and Giuseppina Nigro and Filomena Catapano and Alessandro Retin{\`o} and Chen, \{Christopher H.\} and Emiliya Yordanova and Oreste Pezzi and Khatuna Chargazia and Oleg Kharshiladze and Diana Kvaratskhelia and Vasconez, \{Christian L.\} and \{Le Conte\}, Olivier and Barbara Giles and Moore, \{Thomas E.\} and Torbert, \{Roy B.\} and Burch, \{Jim L.\}",

note = "Publisher Copyright: {\textcopyright} 2019 Sorriso-Valvo, De Vita, Fraternale, Gurchumelia, Perri, Nigro, Catapano, Retin{\`o}, Chen, Yordanova, Pezzi, Chargazia, Kharshiladze, Kvaracxelia, Vasconez, Le Contel, Giles, Moore, Torbert and Burch.",

year = "2019",

month = jul,

day = "1",

doi = "10.3389/fphy.2019.00108",

language = "English",

volume = "7",

journal = "Frontiers in Physics",

issn = "2296-424X",

number = "JULY",

}

Sorriso-Valvo, L, De Vita, G, Fraternale, F, Gurchumelia, A, Perri, S, Nigro, G, Catapano, F, Retinò, A, Chen, CH, Yordanova, E, Pezzi, O, Chargazia, K, Kharshiladze, O, Kvaratskhelia, D, Vasconez, CL, Le Conte, O, Giles, B, Moore, TE, Torbert, RB & Burch, JL 2019, 'Sign singularity of the local energy transfer in space plasma turbulence', Frontiers in Physics, vol. 7, no. JULY, 93. https://doi.org/10.3389/fphy.2019.00108

TY - JOUR

T1 - Sign singularity of the local energy transfer in space plasma turbulence

AU - Sorriso-Valvo, Luca

AU - De Vita, Gaetano

AU - Fraternale, Federico

AU - Gurchumelia, Alexandre

AU - Perri, Silvia

AU - Nigro, Giuseppina

AU - Catapano, Filomena

AU - Retinò, Alessandro

AU - Chen, Christopher H.

AU - Yordanova, Emiliya

AU - Pezzi, Oreste

AU - Chargazia, Khatuna

AU - Kharshiladze, Oleg

AU - Kvaratskhelia, Diana

AU - Vasconez, Christian L.

AU - Le Conte, Olivier

AU - Giles, Barbara

AU - Moore, Thomas E.

AU - Torbert, Roy B.

AU - Burch, Jim L.

N1 - Publisher Copyright: © 2019 Sorriso-Valvo, De Vita, Fraternale, Gurchumelia, Perri, Nigro, Catapano, Retinò, Chen, Yordanova, Pezzi, Chargazia, Kharshiladze, Kvaracxelia, Vasconez, Le Contel, Giles, Moore, Torbert and Burch.

PY - 2019/7/1

Y1 - 2019/7/1

N2 - In weakly collisional space plasmas, the turbulent cascade provides most of the energy that is dissipated at small scales by various kinetic processes. Understanding the characteristics of such dissipative mechanisms requires the accurate knowledge of the fluctuations that make energy available for conversion at small scales, as different dissipation processes are triggered by fluctuations of a different nature. The scaling properties of different energy channels are estimated here using a proxy of the local energy transfer, based on the third-order moment scaling law for magnetohydrodynamic turbulence. In particular, the sign-singularity analysis was used to explore the scaling properties of the alternating positive-negative energy fluxes, thus providing information on the structure and topology of such fluxes for each of the different type of fluctuations. The results show the highly complex geometrical nature of the flux, and that the local contributions associated with energy and cross-helicity nonlinear transfer have similar scaling properties. Consequently, the fractal properties of current and vorticity structures are similar to those of the Alfv\'enic fluctuations.

AB - In weakly collisional space plasmas, the turbulent cascade provides most of the energy that is dissipated at small scales by various kinetic processes. Understanding the characteristics of such dissipative mechanisms requires the accurate knowledge of the fluctuations that make energy available for conversion at small scales, as different dissipation processes are triggered by fluctuations of a different nature. The scaling properties of different energy channels are estimated here using a proxy of the local energy transfer, based on the third-order moment scaling law for magnetohydrodynamic turbulence. In particular, the sign-singularity analysis was used to explore the scaling properties of the alternating positive-negative energy fluxes, thus providing information on the structure and topology of such fluxes for each of the different type of fluctuations. The results show the highly complex geometrical nature of the flux, and that the local contributions associated with energy and cross-helicity nonlinear transfer have similar scaling properties. Consequently, the fractal properties of current and vorticity structures are similar to those of the Alfv\'enic fluctuations.

KW - Dissipation

KW - Magnetosphere

KW - Singularity

KW - Space plasmas

KW - Turbulence

UR - https://www.scopus.com/pages/publications/85069858438

U2 - 10.3389/fphy.2019.00108

DO - 10.3389/fphy.2019.00108

M3 - Article

AN - SCOPUS:85069858438

SN - 2296-424X

VL - 7

JO - Frontiers in Physics

JF - Frontiers in Physics

IS - JULY

M1 - 93

ER -

Sign singularity of the local energy transfer in space plasma turbulence

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Keywords

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