Hostname: page-component-cd9895bd7-7cvxr Total loading time: 0 Render date: 2024-12-26T16:18:45.748Z Has data issue: false hasContentIssue false

Solar wind collisional heating

Published online by Cambridge University Press:  22 May 2017

Oreste Pezzi*
Affiliation:
Dipartimento di Fisica, Università della Calabria, 87036 Rende (CS), Italy
*
Email address for correspondence: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

To properly describe heating in weakly collisional turbulent plasmas such as the solar wind, interparticle collisions should be taken into account. Collisions can convert ordered energy into heat by means of irreversible relaxation towards the thermal equilibrium. Recently, Pezzi et al. (Phys. Rev. Lett., vol. 116, 2016a, 145001) showed that the plasma collisionality is enhanced by the presence of fine structures in velocity space. Here, the analysis is extended by directly comparing the effects of the fully nonlinear Landau operator and a linearized Landau operator. By focusing on the relaxation towards the equilibrium of an out of equilibrium distribution function in a homogeneous force-free plasma, here it is pointed out that it is significant to retain nonlinearities in the collisional operator to quantify the importance of collisional effects. Although the presence of several characteristic times associated with the dissipation of different phase space structures is recovered in both the cases of the nonlinear and the linearized operators, the influence of these times is different in the two cases. In the linearized operator case, the recovered characteristic times are systematically larger than in the fully nonlinear operator case, this suggesting that fine velocity structures are dissipated more slowly if nonlinearities are neglected in the collisional operator.

Type
Research Article
Copyright
© Cambridge University Press 2017 

1 Introduction

Since the beginning of the last century, many theoretical efforts have been performed to model natural and laboratory plasmas. One of the first attempts to describe the interplanetary medium and its interaction with planetary magnetospheres was conducted by Chapman & Ferraro (Reference Chapman and Ferraro1930, Reference Chapman and Ferraro1931), widely considered the fathers of the magnetohydrodynamics (MHD) theory. Their main intuition was to treat plasmas, approximated by neutral conducting fluids, as self-consistent media. One of the basic assumptions of this framework is that interparticle collisions are sufficiently strong to maintain a local thermodynamical equilibrium, e.g. the particle velocity distribution function (VDF) is close to the equilibrium Maxwellian shape. This approach is still widely adopted to analyse plasma dynamics at large scales and many models have been developed to study the features of MHD turbulence (Elsässer Reference Elsässer1950; Chandrasekhar Reference Chandrasekhar1956; Iroshnikov Reference Iroshnikov1964; Kraichnan Reference Kraichnan1965; Moffatt Reference Moffatt1978; Parker Reference Parker1979; Dobrowolny, Mangeney & Veltri Reference Dobrowolny, Mangeney and Veltri1980a ,Reference Dobrowolny, Mangeney and Veltri b ; Ng & Bhattacharjee Reference Ng and Bhattacharjee1996; Matthaeus et al. Reference Matthaeus, Zank, Smith and Oughton1999; Verdini, Velli & Buchlin Reference Verdini, Velli and Buchlin2009; Bruno & Carbone Reference Bruno and Carbone2013; Howes & Nielson Reference Howes and Nielson2013; Pezzi et al. Reference Pezzi, Parashar, Servidio, Valentini, Vásconez, Yang, Malara, Matthaeus and Veltri2017a ,Reference Pezzi, Parashar, Servidio, Valentini, Vásconez, Yang, Malara, Matthaeus and Veltri b ). One of the most studied natural plasmas is the solar wind, which is the high temperature, low density, supersonic flow emitted from the solar atmosphere. The solar wind is a strongly turbulent flow: the typical Reynolds number is approximately $Re\approx 10^{5}$ (Matthaeus et al. Reference Matthaeus, Dasso, Weygand, Milano, Smith and Kivelson2005); fluctuations are broadband and often exhibit a power-law spectra; several indicators of intermittency are routinely observed (Bruno & Carbone Reference Bruno and Carbone2013; Matthaeus et al. Reference Matthaeus, Wan, Servidio, Greco, Osman, Oughton and Dmitruk2015). Despite the fact that the solar wind is usually approached in terms of MHD turbulence, spacecraft in situ measurements reveal highly complex features, which go beyond the fluid MHD approach. Once the energy is transferred by turbulence towards smaller scales close to the ion inertial scales, kinetic physics signatures are often observed (Sahraoui, Galtier & Belmont Reference Sahraoui, Galtier and Belmont2007; Alexandrova et al. Reference Alexandrova, Carbone, Veltri and Sorriso-Valvo2008; Gary, Saito & Narita Reference Gary, Saito and Narita2010; Bruno & Carbone Reference Bruno and Carbone2013). The particle VDF often displays a distorted out-of-equilibrium shape characterized by the presence of non-Maxwellian features such as temperature anisotropies, particle beams along the local magnetic field direction and ring-like structures (Marsch Reference Marsch2006; Kasper, Lazarus & Gary Reference Kasper, Lazarus and Gary2008; Maruca, Kasper & Bale Reference Maruca, Kasper and Bale2011; Maruca et al. Reference Maruca, Bale, Sorriso-Valvo, Kasper and Stevens2013; He et al. Reference He, Tu, Marsch, Chen, Wang, Pei, Zhang, Salem and Bale2015). The principal models to take into account kinetic effects are based on the assumption that the plasma is collisionless, e.g. collisions are far too weak to produce any significant effect on the plasma dynamics (Valentini et al. Reference Valentini, Carbone, Veltri and Mangeney2005; Daughton et al. Reference Daughton, Roytershteyn, Albright, Karimabadi, Yin and Bowers2009; Parashar et al. Reference Parashar, Shay, Cassak and Matthaeus2009; Camporeale & Burgess Reference Camporeale and Burgess2011; Valentini et al. Reference Valentini, Califano, Perrone, Pegoraro and Veltri2011a ; Valentini, Perrone & Veltri Reference Valentini, Perrone and Veltri2011b ; Greco et al. Reference Greco, Valentini, Servidio and Matthaeus2012; Perrone et al. Reference Perrone, Valentini, Servidio, Dalena and Veltri2012; Servidio et al. Reference Servidio, Valentini, Califano and Veltri2012; Valentini et al. Reference Valentini, Servidio, Perrone, Califano, Matthaeus and Veltri2014; Franci et al. Reference Franci, Verdini, Matteini, Landi and Hellinger2015; Servidio et al. Reference Servidio, Valentini, Perrone, Greco, Califano, Matthaeus and Veltri2015; Valentini et al. Reference Valentini, Perrone, Stabile, Pezzi, Servidio, De Marco and Consolini2016).

We would point out that, in order to comprehend the heating mechanisms of the solar wind, collisional effects should be considered. Indeed collisions are the unique mechanism able to produce irreversible heating from a thermodynamic point of view. Furthermore, to show that collisions can be neglected, the shape of the particle VDF is usually assumed to be close to the equilibrium Maxwellian (Spitzer Reference Spitzer1956; Hernandez & Marsch Reference Hernandez and Marsch1985; Maruca et al. Reference Maruca, Bale, Sorriso-Valvo, Kasper and Stevens2013). This approximation may be problematic for weakly collisional turbulent plasmas, where kinetic physics strongly distorts the particle VDFs and produces fine structure in velocity space. Collisional effects, which explicitly depend on gradients in velocity space, may be enhanced by the presence of these small-scale structures in velocity space (Pezzi, Valentini & Veltri Reference Pezzi, Valentini and Veltri2016a ) (hereafter Paper I). Indeed, in Paper I we showed that the collisional thermalization of fine velocity structures occurs on much smaller times with respect to the usual Spitzer–Harm time (Spitzer Reference Spitzer1956) $\unicode[STIX]{x1D708}_{SH}^{-1}$ (where $\unicode[STIX]{x1D708}_{SH}\simeq 8\times (0.714\unicode[STIX]{x03C0}ne^{4}\ln \unicode[STIX]{x1D6EC})/(m^{0.5}(3k_{B}T)^{3/2})$ , and $n$ , $e$ , $\ln \unicode[STIX]{x1D6EC}$ , $m$ , $k_{B}$ and $T$ are respectively the particle number density, the unit electric charge, the Coulomb logarithm, the Boltzmann constant and the plasma temperature). The smallest characteristic times may be comparable with the characteristic times of other physical processes. Therefore, collisions could play a significant role into the dissipation of strong gradients in the VDF, thus contributing to the plasma heating.

In this paper we focus on the importance of retaining nonlinearities in the collisional operators. In particular, by means of numerical simulations of a homogeneous force-free plasma, we describe the collisional relaxation towards the equilibrium of an initial VDF which exhibits strong non-Maxwellian signatures. Collisions among particles of the same species are here modelled through the fully nonlinear Landau operator and a linearized Landau operator. A detailed comparison concerning the effects of the two operators indicates that retaining nonlinearities in the collisional integral is crucial to assign proper importance to collisional effects. Indeed, both operators are able to highlight the presence of several characteristic times associated with the dissipation of fine velocity structures. However, the magnitude of these times is different if nonlinearities are neglected: in the linearized operator case, the characteristic times are systematically larger compared to the case of the fully nonlinear operator. This indicates that, when nonlinearities are not taken into account in the mathematical form of the collisional operator, fine velocity structures are dissipated much slower. Results herein described support the idea that to properly quantify the enhancement of collisional effects and, hence, to correctly compare collisional times with other dynamical times, it is important to adopt nonlinear collisional operators.

We would remark that, since the Landau operator is demanding from a computational perspective, self-consistent high-resolution simulations cannot currently be afforded and we are forced to restrict ourselves to the case of a force-free homogeneous plasma, where both force and advection terms have been neglected. This approximation represents a caveat of the work here presented and future studies will be devoted to the generalization of the results here shown to the self-consistent case.

The paper is organized as follows: in § 2 the solar wind heating problem is revisited in order to address and motivate our work. Then, in § 3 we give a brief description of the numerical codes and the adopted methods of analysis. Numerical results of our simulations are also reported and discussed in detail. Finally, in § 4 we conclude and summarize.

2 Solar wind heating: a huge problem

As introduced above, the solar wind is a weakly collisional, strongly turbulent medium (Bruno & Carbone Reference Bruno and Carbone2013). Several observations indicate that the solar wind is incessantly heated during its travel through the heliosphere: the temperature decay along the radial distance is indeed much slower than the decay expected with adiabatic models of the wind expansion (Marsch et al. Reference Marsch, Muhlhauser, Schwenn, Rosenbauer, Pilipp and Neubauer1982; Goldstein et al. Reference Goldstein, Neugebauer, Phillips, Bame, Gosling, McComas, Wang, Sheeley and Suess1996; Marino et al. Reference Marino, Sorriso-Valvo, Carbone, Noullez, Bruno and Bavassano2008; Cranmer et al. Reference Cranmer, Matthaeus, Breech and Kasper2009). Therefore, some local heating mechanisms must play a significant role to supply the energy needed to heat the plasma. Numerous scenarios have been proposed to understand the plasma heating and a long-standing debate about which processes are preferred is still waiting for a clear and definitive answer (see Bruno & Carbone (Reference Bruno and Carbone2013) and references therein). Among these processes, it is widely known that the turbulence efficiently contributes to the local heating of the solar wind (Sorriso-Valvo et al. Reference Sorriso-Valvo, Marino, Carbone, Noullez, Lepreti, Veltri, Bruno, Bavassano and Pietropaolo2007; Marino et al. Reference Marino, Sorriso-Valvo, Carbone, Noullez, Bruno and Bavassano2008; Sahraoui et al. Reference Sahraoui, Goldstein, Robert and Khotyaintsev2009), since it can efficiently transfer a significant amount of energy towards smaller scales, where dissipative mechanisms are at work. In fact, in a turbulent flow, much more energy is transferred towards smaller scales with respect to a laminar flow: the ratio between the energy transfer flux due to turbulence at a certain scale with respect to the heating production due to dissipation at the same scale is proportional to the Reynolds number $Re$ , thus indicating that the energy transfer towards smaller scales gets more efficient as the flow becomes more turbulent.

In the simple neutral fluid scenario, the cascade is arrested once that the dissipative scale is reached (Frisch Reference Frisch1995). On the other hand, the cascade evolves in a more complex way in a plasma: the presence of other processes (for example dispersion and kinetic effects) strongly modify the cascade before reaching the dissipative scale. A relatively wide agreement has been achieved concerning the importance of turbulence for transferring energy towards smaller scales and many scenarios have been proposed to explain the transition from the inertial range towards the kinetic scales and the nature of dissipative processes. These scenarios are often based on the ‘collisionless’ assumption, that is justified by the fact that the Spitzer–Harm collisional time (Spitzer Reference Spitzer1956) is much larger than other dynamical times. We would remark that two important caveats should be considered.

First, any mechanism which does not consider collisions is not able to describe the last part of the heating process, namely the heat production due to the irreversible dissipation of phase space structures and the approach towards the thermal equilibrium. For example, several mechanisms (e.g. nonlinear waves) can indeed increase the particle temperature, evaluated as the second-order moment of the particle distribution function, by producing non-Maxwellian features as beams of trapped particles. However, this temperature growth due to the beam production does not represent a temperature growth in the thermodynamic sense, because the beam presence makes the system out of equilibrium. The particle beam can be instead interpreted as a form of free energy stored into the VDF. This energy is not in general converted into heat by means of irreversible processes but it can be also transformed in other forms of ordered energy (e.g. through micro-instabilities) (Lesur, Diamond & Kosuga Reference Lesur, Diamond and Kosuga2014). Collisions are the unique mechanism able to degrade this information into heat by approaching the thermal equilibrium, thus producing heating in the general thermodynamic and irreversible sense.

Second, the evaluation of the Spitzer–Harm collisional time strictly assumes that the VDF shape is close to the equilibrium Maxwellian. This assumption may not be true in the solar wind (Marsch Reference Marsch2006; Servidio et al. Reference Servidio, Valentini, Perrone, Greco, Califano, Matthaeus and Veltri2015), where the VDF’s shape is strongly perturbed by kinetic turbulence. In this direction, by focusing on the collisional relaxation in a homogeneous force-free plasma where collisions are modelled with the fully nonlinear Landau operator (Landau Reference Landau1936), we recently showed that fine velocity structures are dissipated much faster than global non-thermal features such as temperature anisotropy (Paper I). The entropy production due to the relaxation of the VDF towards the equilibrium occurs on several characteristic times. These characteristic times are associated with the dissipation of particular velocity space structures and can be much smaller than the Spitzer–Harm time (Spitzer Reference Spitzer1956), this indicating that collisions could effectively compete with other processes (e.g. micro-instabilities). In this perspective, high-resolution measurements of the particle VDF in the solar wind are crucial for a proper description of the heating problem (Vaivads et al. Reference Vaivads, Retinó, Soucek, Khotyaintsev, Valentini, Escoubet, Alexandrova, André, Bale and Balikhin2016).

In principle the combination of the turbulent nature of the solar wind with its weakly collisionality may constitute a new scenario to describe solar wind heating. In fact, turbulence is able to transfer energy towards smaller scales. Then, when kinetic scales are reached, since the plasma is weakly collisional, the VDF becomes strongly distorted and exhibits non-Maxwellian features, such as beams, anisotropies and ring-like structures (Belmont et al. Reference Belmont, Mottez, Chust and Hess2008; Chust et al. Reference Chust, Belmont, Mottez and Hess2009; Servidio et al. Reference Servidio, Valentini, Califano and Veltri2012, Reference Servidio, Valentini, Perrone, Greco, Califano, Matthaeus and Veltri2015). The presence of strong gradients in velocity space tends to naturally enhance the effect of collisions, which – ultimately – may become efficient for dissipating these structures and for producing heat.

Based on these last considerations, numerous studies have been recently conducted in order to take into account collisional effects in a weakly collisional plasma such as the solar wind (Filbet & Pareschi Reference Filbet and Pareschi2002; Bobylev & Potapenko Reference Bobylev and Potapenko2013; Pezzi et al. Reference Pezzi, Valentini, Perrone and Veltri2013, Reference Pezzi, Valentini, Perrone and Veltri2014; Escande, Elskens & Doveil Reference Escande, Elskens and Doveil2015; Pezzi, Valentini & Veltri Reference Pezzi, Valentini and Veltri2015b ; Pezzi et al. Reference Pezzi, Valentini and Veltri2016a ; Banón Navarro et al. Reference Banón Navarro, Teaca, Told, Groselj, Crandall and Jenko2016; Hirvijoki et al. Reference Hirvijoki, Lingam, Pfefferlé, Comisso, Candy and Bhattacharjee2016; Tigik et al. Reference Tigik, Ziebell, Yoon and Kontar2016), where collisions are usually introduced by means of a collisional operator at the right-hand side of the Vlasov equation. The choice of the proper collisional operator remains an open problem. Several derivations from first principles (e.g. the Liouville equation) indicate that the most general collisional operators for plasmas are the Lenard–Balescu operator (Balescu Reference Balescu1960; Lenard Reference Lenard1960) or the Landau operator (Landau Reference Landau1936; Akhiezer et al. Reference Akhiezer, Akhiezer, Polovin, Sitenko and Stepanov1986). Both operators are nonlinear ‘Fokker–Planck’-like operators which involve velocity space derivatives and three-dimensional integrals. The Landau operator introduces an upper cutoff of the integrals at the Debye length to avoid the divergence for large impact parameters, while the Balescu–Lenard operator solves this divergence in a more consistent way through the dispersion equation. Therefore, the Balescu–Lenard operator is more general than the Landau operator from this point of view. However, both operators are derived by assuming that the plasma is not extremely far from the thermal equilibrium. Hence, both operators could lack the description of interparticle collisions in a strongly turbulent system. The numerical approach of operators is also much more difficult for the Balescu–Lenard operator with respect to the Landau operator, because it involves the evaluation of the dispersion function. Finally, we would also point out that, as far as we know, an explicit derivation of the Boltzmann operator for plasmas starting from the Liouville equation does not exist (Villani Reference Villani2002). Despite the fact that the adoption of the Boltzmann operator for describing collisional effects in plasmas is questionable from a theoretical perspective, it still represents a valid option since the Boltzmann and Fokker–Planck-like operators such as the Landau operator are intrinsically similar (Landau Reference Landau1936; Bobylev & Potapenko Reference Bobylev and Potapenko2013).

The computational cost to evaluate both the Landau and Balescu–Lenard operators numerically is huge: for $N$ grid points along each direction of the $3D$ $3V$ numerical phase space (three dimensions in physical space and three dimensions in velocity space), the computation of the Landau operator would require approximately $N^{9}$ operations at each time step. In fact, for each point of the six-dimensional grid, a three-dimensional integral must be computed. To avoid this numerical complexity, several simplified operators have been proposed. We may distinguish these simpler operators in two classes. The first type of operators, such as the Bathanar–Gross–Krook (Bhatnagar, Gross & Krook Reference Bhatnagar, Gross and Krook1954; Livi & Marsch Reference Livi and Marsch1986) and the Dougherty operators (Dougherty Reference Dougherty1964; Dougherty & Watson Reference Dougherty and Watson1967; Pezzi, Valentini & Veltri Reference Pezzi, Valentini and Veltri2015a ), model collisions in the realistic three-dimensional velocity space by adopting a simpler structure of the operator. The second class of collisional operators works instead in a reduced, one-dimensional velocity space assuming that the dynamics mainly occurs in one direction. Although this approach is quite ‘unphysical’ (collisions naturally act in three dimensions), these operators can satisfactorily model collisions in laboratory plasmas devices, such as the Penning–Malmberg traps, where the plasma is confined into a long and thin column and the dynamics occurs mainly along a single direction (Anderson & O’Neil Reference Anderson and O’Neil2007a ,Reference Anderson and O’Neil b ; Pezzi et al. Reference Pezzi, Valentini, Perrone and Veltri2013; Pezzi, Camporeale & Valentini Reference Pezzi, Camporeale and Valentini2016b ).

3 Numerical approach and simulation results

As described above, to highlight the importance of nonlinearities present in the collisional operator, here we compare the effects of using the full Landau operator with a model of the linearized Landau operator, obtained by simplifying the structures of the Landau operator coefficients. We restrict ourselves to the case of a force-free homogeneous plasma and we just model collisions between particles of the same species. Our interest is in fact to understand how collisional effects change when the mathematical kernel of the collisional operator is modified. Based on these assumptions, we numerically integrate the following dimensionless collisional evolution equations for the particle distribution function $f(\boldsymbol{v},t)$ :

(3.1) $$\begin{eqnarray}\displaystyle & \displaystyle \frac{\unicode[STIX]{x2202}f(\boldsymbol{v},t)}{\unicode[STIX]{x2202}t}=\unicode[STIX]{x03C0}\left(\frac{3}{2}\right)^{3/2}\frac{\unicode[STIX]{x2202}}{\unicode[STIX]{x2202}v_{i}}\int \text{d}^{3}v^{\prime }\,U_{ij}(\boldsymbol{u})\left[f(\boldsymbol{v}^{\prime },t)\frac{\unicode[STIX]{x2202}f(\boldsymbol{v},t)}{\unicode[STIX]{x2202}v_{j}}-f(\boldsymbol{v},t)\frac{\unicode[STIX]{x2202}f(\boldsymbol{v}^{\prime },t)}{\unicode[STIX]{x2202}v_{j}^{\prime }}\right], & \displaystyle\end{eqnarray}$$
(3.2) $$\begin{eqnarray}\displaystyle & \displaystyle \frac{\unicode[STIX]{x2202}f(\boldsymbol{v},t)}{\unicode[STIX]{x2202}t}=\unicode[STIX]{x03C0}\left(\frac{3}{2}\right)^{3/2}\frac{\unicode[STIX]{x2202}}{\unicode[STIX]{x2202}v_{i}}\int \text{d}^{3}v^{\prime }\,U_{ij}(\boldsymbol{u})\left[f_{0}(\boldsymbol{v}^{\prime })\frac{\unicode[STIX]{x2202}f(\boldsymbol{v},t)}{\unicode[STIX]{x2202}v_{j}}-f(\boldsymbol{v},t)\frac{\unicode[STIX]{x2202}f_{0}(\boldsymbol{v}^{\prime })}{\unicode[STIX]{x2202}v_{j}^{\prime }}\right]. & \displaystyle\end{eqnarray}$$

where $f$ is normalized such that $\int \text{d}^{3}v\,f(\boldsymbol{v})=n=1$ and $U_{ij}(\boldsymbol{u})$ is

(3.3) $$\begin{eqnarray}U_{ij}(\boldsymbol{u})=\frac{\unicode[STIX]{x1D6FF}_{ij}u^{2}-u_{i}u_{j}}{u^{3}},\end{eqnarray}$$

where $\boldsymbol{u}=\boldsymbol{v}-\boldsymbol{v}^{\prime }$ , $u=|\boldsymbol{u}|$ and the Einstein notation is introduced. In (3.1)–(3.2), and from now on, time is scaled to the inverse Spitzer–Harm frequency $\unicode[STIX]{x1D708}_{SH}^{-1}$ (Spitzer Reference Spitzer1956) and velocity to the particle thermal speed $v_{th}$ . Details about the numerical solution of (3.1)–(3.2) can be found in (Pezzi et al. Reference Pezzi, Valentini and Veltri2015a , Reference Pezzi, Valentini and Veltri2016a ). In (3.2), $f_{0}(\boldsymbol{v})$ is the three-dimensional Maxwellian distribution function associated with the initial condition of our simulations $f(\boldsymbol{v},t=0)$ and is built in such a way that density, bulk velocity and temperature of the two distributions $f(\boldsymbol{v},t=0)$ and $f_{0}(\boldsymbol{v})$ are equal. The two equations clearly differ because (3.2) is a linearized model of (3.1). The operator described in (3.2) has been in fact obtained by linearizing the coefficients of the Landau operator. Although this linear operator does not represent the exact linearization of the Landau operator, the procedure here utilized for linearizing the operator (i.e. simplifying only the Fokker–Planck coefficients) is commonly adopted. In the following, we will note that the simulations performed with the linearized operator thermalize to the same final VDF and produce also the same total entropy growth as the nonlinear simulations. This suggests that the term which is not included in the form collisional operator (whose Fokker–Planck coefficients depend on $(f-f_{0})(\boldsymbol{v}^{\prime })$ ) is not extremely relevant in the global thermalization of the system. This approximation corresponds to retain the gradients related to the out-of-equilibrium structures but to neglect their contribution to the integral in the $\boldsymbol{v}^{\prime }$ space. In other words, here we locally consider gradients but we neglect their contribution to the global Fokker–Planck coefficients.

When simulations are completed, we perform the following multi-exponential fit (Curtis, Berry & Bromander Reference Curtis, Berry and Bromander1970; Pezzi et al. Reference Pezzi, Valentini and Veltri2016a ) of the entropy growth $\unicode[STIX]{x0394}S$ to point out the presence of several characteristic times:

(3.4) $$\begin{eqnarray}\unicode[STIX]{x0394}S(t)=\mathop{\sum }_{i=1}^{K}\unicode[STIX]{x0394}S_{i}(1-\text{e}^{-t/\unicode[STIX]{x1D70F}_{i}}),\end{eqnarray}$$

$\unicode[STIX]{x1D70F}_{i}$ being the $i$ th characteristic time, $\unicode[STIX]{x0394}S_{i}$ the growth of entropy related to the characteristic time $\unicode[STIX]{x1D70F}_{i}$ and $K$ is evaluated through a recursive procedure. This procedure has been already adopted in Paper I to highlight the importance of fine velocity structures in the entropy growth. In the following subsections, we report and describe the results of the simulations performed with two different initial distribution functions, already adopted in Paper I. The first initial condition concerns the presence of non-Maxwellian signatures due to a strongly nonlinear wave – an electron acoustic wave (EAW) (Holloway & Dorning Reference Holloway and Dorning1991; Kabantsev, Valentini & Driscoll Reference Kabantsev, Valentini and Driscoll2006; Valentini, ONeil & Dubin Reference Valentini, ONeil and Dubin2006; Anderegg et al. Reference Anderegg, Driscoll, Dubin and ONeil2009a ,Reference Anderegg, Driscoll, Dubin, ONeil and Valentini b ; Johnston et al. Reference Johnston, Tyshetskiy, Ghizzo and Bertrand2009; Valentini et al. Reference Valentini, Perrone, Califano, Pegoraro, Veltri, Morrison and O’Neil2012) – in the core of the distribution function. The EAWs here excited are quite different from another type of electron acoustic fluctuations that occur in a plasma composed of two components at different temperatures (Watanabe & Taniuti Reference Watanabe and Taniuti1977) and can be also observed in the Earth’s magnetosphere (Tokar & Gary Reference Tokar and Gary1984; Lu, Wang & Wang Reference Lu, Wang and Wang2005). The EAWs here excited are undamped waves whose phase speed is close to the thermal speed. It has been shown that, in the usual theory of an equilibrium Maxwellian plasma, these waves are strongly damped; while they can survive if the distribution function is locally modified (and exhibits a flat region) around the wave phase velocity. To generate the nonlinearity in the distribution function and allow these waves to survive, external drivers are usually adopted to force the plasma. EAWs are also characterized by the presence of phase space Bernstein–Green–Kruskal (BGK) structures (Bernstein, Greene & Kruskal Reference Bernstein, Greene and Kruskal1957) in the core of the electron distribution function, associated with trapped particle populations. The second initial distribution is instead a typical VDF recovered in hybrid Vlasov–Maxwell simulations of solar wind decaying turbulence (Servidio et al. Reference Servidio, Valentini, Califano and Veltri2012; Valentini et al. Reference Valentini, Servidio, Perrone, Califano, Matthaeus and Veltri2014; Servidio et al. Reference Servidio, Valentini, Perrone, Greco, Califano, Matthaeus and Veltri2015). The two simulations from which we selected our initial VDF are quite different. Indeed, in the first case, the out-of-equilibrium structures present in the initial VDF are due to the wave–particle interaction with the EAW, which is an almost monochromatic (few excited wavenumbers) electrostatic wave. On the other hand, in the second case, the initial distribution function has been strongly distorted due to the presence of an electromagnetic, turbulent cascade.

3.1 First case study: wave–particle interactions and collisions

Figure 1. (a) Power spectral density of the electric energy $E_{E}(k_{z})$ as a function of the wavenumber $k_{z}$ . (b) Contour plot of $f_{e}(z,v_{z})$ at the time instant when the EAWs is fully developed. The red line represents the coordinate $z=z_{0}$ where the cut is performed. (c) Profile of $f_{e}(z_{0},v_{z})$ as a function of $v_{z}$ .

The first initial condition here adopted, which is a three-dimensional VDF that evolves according to (3.1)–(3.2) in the three-dimensional velocity space, has been designed as follows. We separately performed a $1D$ $1V$ Vlasov-Poisson simulation of a electrostatic plasma composed of kinetic electrons and motionless protons whose resolution, in the $z-v_{z}$ phase space domain, is $N_{z}=256$ , $N_{v_{z}}=1601$ . In order to excite a large amplitude EAW, we forced the system with an external sinusoidal electric field, which has been adiabatically turned on and off to properly trigger the wave. Figure 1(a) reports the power spectral density of the electric energy $E_{E}(k_{z})$ as a function of the wavenumber $k_{z}$ , evaluated at the final time instant of the Vlasov–Poisson simulation (where the EAW is fully developed). Few wavenumbers are significantly excited and the EAW is almost monochromatic. The features of the electric fluctuations spectrum are reflected into the shape of the distribution function, which is locally distorted around the phase speed and presents a clear BGK hole, as reported in figure 1(b). Since the grid size in velocity space is quite small in the current simulation, relatively small velocity scales are dynamically generated during the simulation by wave–particle interaction.

Figure 2. Time history of $\unicode[STIX]{x0394}S$ in the case of the fully nonlinear Landau operator (black) and the linearized Landau operator (red). Blue diamonds indicate the time instants $t=T_{nl,1}=\unicode[STIX]{x1D70F}_{1}^{nl}$ , $t=T_{nl,2}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}$ and $t=T_{nl,3}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}+\unicode[STIX]{x1D70F}_{3}^{nl}$ ; the green triangles refer to $t=T_{lin,1}=\unicode[STIX]{x1D70F}_{1}^{lin}$ , $t=T_{lin,2}=\unicode[STIX]{x1D70F}_{1}^{lin}+\unicode[STIX]{x1D70F}_{2}^{lin}$ and $t=T_{lin,3}=\unicode[STIX]{x1D70F}_{1}^{lin}+\unicode[STIX]{x1D70F}_{2}^{lin}+\unicode[STIX]{x1D70F}_{3}^{lin}$ .

Then, we selected the spatial point $z_{0}$ in the numerical domain (red vertical line in figure 1 b), where this BGK-like phase space structure displays its maximum velocity width, and we considered the velocity profile $\hat{f}_{e}(v_{z})=f_{e}(z_{0},v_{z})$ , whose shape as a function of $v_{z}$ is reported in figure 1(c). $\hat{f}_{e}$ is highly distorted due to nonlinear wave–particle interactions and exhibits sharp velocity gradients (bumps, holes, spikes around the resonant speed). Finally, by evaluating the density $n_{e}$ , the bulk speed $V_{e}$ and the temperature $T_{e}$ of $\hat{f}_{e}$ , we built up the three-dimensional VDF $f(v_{x},v_{y},v_{z})=f_{M}(v_{x})f_{M}(v_{y})\hat{f}_{e}(v_{z})$ , which represents our initial condition, with $f_{M}$ the one-dimensional Maxwellian associated with $\hat{f}_{e}$ . We remark that this VDF does not exhibit any temperature anisotropy but it still exhibits strong non-Maxwellian deformations along $v_{z}$ , due to the presence of trapped particles, which make the system far from thermal equilibrium. The three-dimensional velocity domain is here discretized by $N_{v_{x}}=N_{v_{y}}=51$ and $N_{v_{z}}=1601$ grid points in the region $v_{i}=[-v_{max},v_{max}]$ , with $v_{max}=6v_{th}$ and $i=x,y,z$ , while boundary conditions assume that the distribution function is set equal to zero for $|v_{j}|>v_{max}$ .

Since no temperature anisotropies are present, the evolution of the total temperature and of the temperatures along each direction are trivial, since the total temperature is preserved. On the other hand, the evolution of the entropy variation $\unicode[STIX]{x0394}S=S(t)-S(0)$ ( $S=-\int f\ln f\,\text{d}^{3}v$ ) gives information about the approach towards equilibrium. The time history of $\unicode[STIX]{x0394}S$ obtained with the nonlinear Landau operator (black) and with the linearized Landau operator (red) are shown in figure 2. Since the initial condition and the equilibrium Maxwellian reached under the effect of collisions is the same for both operators, the total entropy growth $\unicode[STIX]{x0394}S$ is the same in the two cases. In other words, the free energy contained in the out-of-equilibrium structures in the initial VDF produces the same entropy growth in absolute terms but the growth occurs on different time scales in the two cases. Indeed, in the nonlinear operator case the entropy grows much faster ( $\simeq 1\unicode[STIX]{x1D708}_{SH}^{-1}$ ) compared to the linearized operator case ( $\simeq 4\unicode[STIX]{x1D708}_{SH}^{-1}$ ).

Figure 3. Distribution function $f(v_{x}=0,v_{y}=0,v_{z})$ as a function of $v_{z}$ , obtained in the case of the fully nonlinear Landau operator. Panels from (a) to (d) respectively display the time instants $t=T_{nl,1}=\unicode[STIX]{x1D70F}_{1}^{nl}$ (a), $t=T_{nl,2}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}$ (b), $t=T_{nl,3}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}+\unicode[STIX]{x1D70F}_{3}^{nl}$ (c) and $t=t_{fin}$ (d). Results for the linearized Landau operator are qualitatively the same with the primary difference being that $\unicode[STIX]{x1D70F}_{j}^{nl}$ is substantially smaller than $\unicode[STIX]{x1D70F}_{j}^{lin}$ for each value of $j$ .

To quantify the presence of several characteristic times, we perform the multi-exponential fit of (3.4) on the entropy growth curves reported in figure 2. The analysis of the growth recovered in the fully nonlinear Landau operator indicates that three different characteristic times are recovered in the entropy growth:

  1. (i) $\unicode[STIX]{x1D70F}_{1}^{nl}=3.5\times 10^{-3}\,\unicode[STIX]{x1D708}_{SH}^{-1}\rightarrow \unicode[STIX]{x0394}S_{1}^{nl}/\unicode[STIX]{x0394}S_{tot}=13\,\%$ ,

  2. (ii) $\unicode[STIX]{x1D70F}_{2}^{nl}=1.3\times 10^{-1}\,\unicode[STIX]{x1D708}_{SH}^{-1}\rightarrow \unicode[STIX]{x0394}S_{2}^{nl}/\unicode[STIX]{x0394}S_{tot}=42\,\%$ ,

  3. (iii) $\unicode[STIX]{x1D70F}_{3}^{nl}=4.9\times 10^{-1}\,\unicode[STIX]{x1D708}_{SH}^{-1}\rightarrow \unicode[STIX]{x0394}S_{3}^{nl}/\unicode[STIX]{x0394}S_{tot}=40\,\%$ .

As discussed in Paper I, the presence of several characteristic times is associated with the dissipation of different velocity space structures. Figure 3 reports $f(v_{x}=v_{y}=0,v_{z})$ as a function of $v_{z}$ at the time instants $t=T_{nl,1}=\unicode[STIX]{x1D70F}_{1}^{nl}$ (a), $t=T_{nl,2}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}$ (b), $t=T_{nl,3}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}+\unicode[STIX]{x1D70F}_{3}^{nl}$ (c) and $t=t_{fin}$ (d), These time instants are displayed in figure 2 with blue diamonds. After the time $t=T_{nl,1}=\unicode[STIX]{x1D70F}_{1}^{nl}$ (a), steep spikes visible in figure 1(b) are almost completely smoothed out; then, at time $t=T_{nl,2}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}$ (b), the remaining plateau region is significantly rounded off, only a gentle shoulder being left; finally, after a time $t=T_{nl,3}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}+\unicode[STIX]{x1D70F}_{3}^{nl}$ (c), the collisional relaxation to equilibrium is completed for the most part. A small percentage $\simeq 5\,\%$ of the total entropy growth is finally recovered for larger times and corresponds to the final approach to the equilibrium Maxwellian (d).

By performing the same analysis for the linearized Landau operator case, three characteristic times are also recovered:

  1. (i) $\unicode[STIX]{x1D70F}_{1}^{lin}=1.1\times 10^{-2}\,\unicode[STIX]{x1D708}_{SH}^{-1}\rightarrow \unicode[STIX]{x0394}S_{1}^{lin}/\unicode[STIX]{x0394}S_{tot}=11\,\%$ ,

  2. (ii) $\unicode[STIX]{x1D70F}_{2}^{lin}=2.7\times 10^{-1}\,\unicode[STIX]{x1D708}_{SH}^{-1}\rightarrow \unicode[STIX]{x0394}S_{2}^{lin}/\unicode[STIX]{x0394}S_{tot}=23\,\%$ ,

  3. (iii) $\unicode[STIX]{x1D70F}_{3}^{lin}=1.5\,\unicode[STIX]{x1D708}_{SH}^{-1}\rightarrow \unicode[STIX]{x0394}S_{3}^{lin}/\unicode[STIX]{x0394}S_{tot}=63\,\%$ .

These characteristic times are systematically larger than the times recovered in the nonlinear operator case. The shape of the distribution function after each characteristic time (not shown here) is quite similar to the shape recovered in the case of the fully nonlinear operator evolution. The process of dissipation of fine velocity structure is, hence, qualitatively similar if one adopts nonlinear or linearized operators. However, significant quantitative differences occur: similar profiles in velocity space are indeed reached at very different times, with the characteristic times recovered in the linearized case significantly larger (approximately 4 times) than the times recovered in the nonlinear operator case.

Therefore, from a qualitative point of view, both operators are able to recover the fact that fine velocity space structures are dissipated faster as their scale become finer (i.e. as the velocity space gradients become stronger). However, fine velocity structures are dissipated slower by linearizing the collisional operator. Moreover, it is also worth mentioning that the amount of entropy growth associated with each characteristic time slightly changes by ignoring nonlinearities. For example, in the case of the fully nonlinear Landau operator, approximately 55 % of the total entropy growth is produced when the initial spikes and the successive flat plateau are dissipated. On the other hand, in the linearized operator case, only approximately the 30 % of the total entropy growth is associated with these processes.

Figure 4. (a) Omni-directional power spectral densities (PSDs) of the magnetic energy $E_{B}(k_{\bot })$ (black line) and of the electric energy $E_{E}(k_{\bot })$ (red line) as a function of the perpendicular wavenumber $k_{\bot }$ . PSDs have been evaluated at the time instant where the turbulent activity is maximum. (b) Iso-surface of the initial distribution function. Red, green and blue axes refer to $v_{x}$ , $v_{y}$ and $v_{z}$ , respectively.

3.2 Second case study: kinetic turbulence and collisions

To support the scenario described in the previous section, here we focus on a second initial condition. This initial VDF has been selected from a $2D$ $3V$ hybrid Vlasov-Maxwell numerical simulation of decaying turbulence in solar wind-like conditions (Valentini et al. Reference Valentini, Travnicek, Califano, Hellinger and Mangeney2007, Reference Valentini, Servidio, Perrone, Califano, Matthaeus and Veltri2014). The hybrid Vlasov–Maxwell simulation, whose resolution is $N_{x}=N_{y}=512$ and $N_{v_{x}}=N_{v_{y}}=N_{v_{z}}=51$ , is initialized with an out-of-the-plane background magnetic field. Then, magnetic and bulk speed perturbations at large, MHD scales are introduced. As a result of nonlinear couplings among the fluctuations, the energy cascades towards smaller kinetic scales. Hence, the particle VDF strongly departs from the thermal equilibrium due to the presence of kinetic turbulence and exhibits a potato-like shape similar to solar wind in situ observations (Marsch Reference Marsch2006). The omni-directional power spectral densities of the magnetic (black line) and electric energy (red line), evaluated at the time instant where the turbulent activity is maximum, are reported in figure 4(a): clearly a broadband spectrum is recovered. The iso-contour of the initial VDF, selected where non-Maxwellian effects are strongest (Servidio et al. Reference Servidio, Valentini, Perrone, Greco, Califano, Matthaeus and Veltri2015), is shown in figure 4(b). The VDF exhibits a hole-like structure in the upper part of the box and a thin ring-like structure in the bottom part of the box and is clearly elongated on the $v_{z}$ direction. Compared to the first case study, the current distribution function reflects the presence of a spectrum of excited wavenumbers and it contains several kinds of distortions, not only concentrated around the resonant speed as in the previous case.

In Paper I we showed that, once velocity space gradients are artificially smoothed out through a fitting procedure, the presence of several characteristic times associated with the dissipation of fine velocity structures is definitively lost. Here, we instead compare the evolution towards the equilibrium of this initial condition under the effect of the fully nonlinear Landau operator (3.1) and the linearized Landau operator (3.2). The velocity domain is here discretized with $N_{v_{x}}=N_{v_{y}}=N_{v_{z}}=51$ points. Note that, compared to the first case study, the resolution is here lower and it cannot be increased due to the computational cost of the hybrid Vlasov–Maxwell code. Therefore, the quite small velocity scales recovered in the first case study (spikes around the resonant speed etc.) are not present in this case.

Figure 5 reports the entropy growth obtained with the fully nonlinear Landau operator (black) and with its linearized version (red). The entropy growth is, also here, slower in the linearized operator case compared to the fully nonlinear operator case. To quantify the different evolution observed in figure 5, we perform the multi-exponential fit (Curtis et al. Reference Curtis, Berry and Bromander1970; Pezzi et al. Reference Pezzi, Valentini and Veltri2016a ) described in (3.4).

Figure 5. Time history of $\unicode[STIX]{x0394}S$ in the case of the fully nonlinear Landau operator (black) and the linearized Landau operator (red). Blue diamonds indicate the time instants $t=T_{nl,1}=\unicode[STIX]{x1D70F}_{1}^{nl}$ and $t=T_{nl,2}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}$ ; the green triangles refer to $t=T_{lin,1}=\unicode[STIX]{x1D70F}_{1}^{lin}$ and $t=T_{lin,2}=\unicode[STIX]{x1D70F}_{1}^{lin}+\unicode[STIX]{x1D70F}_{2}^{lin}$ .

The analysis performed in the case of the fully nonlinear operator indicates that the entropy grows with two characteristic times:

  1. (i) $\unicode[STIX]{x1D70F}_{1}^{nl}=0.20\,\unicode[STIX]{x1D708}_{SH}^{-1}\rightarrow \unicode[STIX]{x0394}S_{1}^{nl}/\unicode[STIX]{x0394}S_{tot}=26\,\%$

  2. (ii) $\unicode[STIX]{x1D70F}_{2}^{nl}=0.82\,\unicode[STIX]{x1D708}_{SH}^{-1}\rightarrow \unicode[STIX]{x0394}S_{2}^{nl}/\unicode[STIX]{x0394}S_{tot}=74\,\%$

As in the case described in the previous section, each characteristic time is associated with the dissipation of a different out-of-equilibrium features. Figure 6 reports the iso-surface of the particle VDF at the time $t=T_{nl,1}=\unicode[STIX]{x1D70F}_{1}^{nl}$ (a) and at the time $t=T_{nl,2}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}$ . At $t=T_{nl,1}$ , the initial hole-like structure and the slight ring-like signature have been significantly smoothed out. Then, at $t=T_{nl,2}$ , the approach towards the equilibrium is almost complete, the VDF shape becomes almost Maxwellian. Only a slight temperature anisotropy, which is finally thermalized in the late stage of the simulation, is still recovered. The approach towards the equilibrium confirms that small-scale gradients are dissipated quite fast, while the final approach towards the equilibrium – concerning also the thermalization of temperature anisotropy – occurs on larger characteristic times.

Figure 6. Iso-surface of the distribution function, obtained in the case of the fully nonlinear Landau operator. Panels (a) and (b) respectively display the time instants $t=T_{nl,1}=\unicode[STIX]{x1D70F}_{1}^{nl}$ and $t=T_{nl,2}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}$ . Red, green and blue axes refer to $v_{x}$ , $v_{y}$ and $v_{z}$ , respectively. The results for the linearized Landau operator are qualitatively the same with the primary difference being that $\unicode[STIX]{x1D70F}_{j}^{nl}$ is substantially smaller than $\unicode[STIX]{x1D70F}_{j}^{lin}$ for each value of $j$ .

In the linearized operator case, two characteristic times are also recovered:

  1. (i) $\unicode[STIX]{x1D70F}_{1}^{lin}=0.54\,\unicode[STIX]{x1D708}_{SH}^{-1}\rightarrow \unicode[STIX]{x0394}S_{1}^{nl}/\unicode[STIX]{x0394}S_{tot}=16\,\%$

  2. (ii) $\unicode[STIX]{x1D70F}_{2}^{lin}=2.60\,\unicode[STIX]{x1D708}_{SH}^{-1}\rightarrow \unicode[STIX]{x0394}S_{2}^{nl}/\unicode[STIX]{x0394}S_{tot}=84\,\%$

As described for the first case study, these recovered characteristic times are systematically larger (approximately three times) compared to the times recovered in the fully nonlinear operator case. The amount of entropy growth associated with each characteristic time is also different, a smaller amount of entropy growth is indeed associated with the fastest characteristic time when nonlinearities are neglected. The results here described confirm the insights described in the previous section. The evolution obtained with the two operators is qualitatively similar: in both cases, several characteristic times are recovered in the entropy growth and these characteristic times are associated with the dissipation of different velocity space structures. However, the observed evolutions are different from a quantitative point of view: the recovered characteristic times are very different in the two cases, and are significantly larger in the case of the linearized operator.

As described in Paper I, in the first case study, much smaller characteristic times are in general recovered compared to the second case study, probably since the numerical resolution in the second case study is approximately $30$ times lower compared to the first case study and the sharp velocity gradients present in the first case study (figure 1 c) are not accessible in the second case study (figure 4 b). The presence of finer velocity structures in the first case compared to the second case introduces smaller characteristic times.

4 Conclusion

To summarize, here we discussed in detail the importance of considering collisions in the description of the weakly collisional plasmas. Collisions are enhanced by the presence of fine velocity space structures, such as the ones naturally generated by kinetic turbulence in the solar wind; therefore, they could play a role into the conversion of the VDF’s free energy into heat, by means of irreversible processes.

In particular, we focused on the importance of retaining nonlinearities in the collisional operator by performing a comparative analysis of the collisional relaxation of an out-of-equilibrium initial VDF. Collisions have been modelled by means of two collisional operators: the fully nonlinear Landau operator and a linearized Landau operator. Due to the demanding computational cost of the collisional integral, we restricted ourselves to the collisional relaxation in a force-free homogeneous plasma. Our results must be clearly extended to the more general, self-consistent case; however, performing a high-resolution collisional simulation cannot currently be afforded.

The cases of study here analysed indicate that both nonlinear and linearized collisional operators are able to detect the presence of several time scales associated with the collisional dissipation of small velocity scales in the particle VDF. A possible explanation of this behaviour is that the linearized operator also involves gradients in its structure while it does not describe the ‘second-order’ gradients related to the Fokker–Planck coefficients of the operator; therefore it is able to recover the presence of several characteristic times. The general message given in Paper I, namely that the presence of sharp velocity space gradients speeds up the entropy growth of the system, is confirmed also in the case of the linearized operator: indeed, the fastest recovered characteristic times are significantly smaller than the common Spitzer–Harm collisional time (Spitzer Reference Spitzer1956).

However, we would point out that the importance of the fine velocity structures is weakened if nonlinearities are ignored in the collisional operator. In the case of a linearized collisional operator, slower characteristic times are systematically recovered with respect to the nonlinear operator case. This indicates that, when one neglects the nonlinearities of the collisional integral, fine velocity structures are dissipated slower. Therefore, to properly address the role of collisions and to attribute them the correct relevance with respect to other physical processes (Gary Reference Gary1993; Matthaeus et al. Reference Matthaeus, Oughton, Osman, Servidio, Wan, Gary, Shay, Valentini, Roytershteyn and Karimabadi2014; Tigik et al. Reference Tigik, Ziebell, Yoon and Kontar2016), nonlinearities should be explicitly considered.

Acknowledgements

Dr Pezzi would sincerely thank Professor P. Veltri, Dr F. Valentini and Dr D. Perrone for the fruitful discussions which significantly contributed to the construction of this work. Dr Pezzi would also thank the anonymous Referees for their suggestions which improved the quality of this work. Numerical simulations here discussed have been run on the Fermi parallel machine at Cineca (Italy), within the Iscra–C project IsC26–COLTURBO and on the Newton parallel machine at University of Calabria (Rende, Italy). This work has been supported by the Agenzia Spaziale Italiana under the contract no. ASI-INAF 2015-039-R.O ‘Missione M4 di ESA: Partecipazione Italiana alla fase di assessment della missione THOR’.

References

Akhiezer, A. I., Akhiezer, I. A., Polovin, R. V., Sitenko, A. G. & Stepanov, K. N. 1986 Plasma Electrodynamics, vol. 1. Pergamon.Google Scholar
Alexandrova, O., Carbone, V., Veltri, P. & Sorriso-Valvo, L. 2008 Small-scale energy cascade of the solar wind turbulence. Astrophys. J. 674, 1153.CrossRefGoogle Scholar
Anderegg, F., Driscoll, C. F., Dubin, D. H. E. & ONeil, T. M. 2009a Measurement of correlation-enhanced collision rates. Phys. Rev. Lett. 102 (9), 095001.CrossRefGoogle ScholarPubMed
Anderegg, F., Driscoll, C. F., Dubin, D. H. E., ONeil, T. M. & Valentini, F. 2009b Electron acoustic waves in pure ion plasmas a. Phys. Plasmas 16 (5), 055705.CrossRefGoogle Scholar
Anderson, M. W. & O’Neil, T. M. 2007a Eigenfunctions and eigenvalues of the Dougherty collision operator. Phys. Plasmas 14, 052103.CrossRefGoogle Scholar
Anderson, M. W. & O’Neil, T. M. 2007b Collisional damping of plasma waves on a pure electron plasma column. Phys. Plasmas 14, 112110.CrossRefGoogle Scholar
Balescu, R. 1960 Irreversible processes in ionized gases. Phys. Fluids 3 (1), 5263.CrossRefGoogle Scholar
Banón Navarro, A., Teaca, B., Told, D., Groselj, D., Crandall, P. & Jenko, F. 2016 Structure of plasma heating in gyrokinetic alfvénic turbulence. Phys. Rev. Lett. 117, 245101.Google Scholar
Belmont, G., Mottez, F., Chust, T. & Hess, S. 2008 Existence of non-Landau solutions for Langmuir waves. Phys. Plasmas 15 (5), 052310.CrossRefGoogle Scholar
Bernstein, I. B., Greene, J. M. & Kruskal, M. D. 1957 Exact nonlinear plasma oscillations. Phys. Rev. 108 (3), 546.CrossRefGoogle Scholar
Bhatnagar, P. L., Gross, E. P. & Krook, M. 1954 A model for collision processes in gases. I. Small amplitude processes in charged and neutral one-component systems. Phys. Rev. 94, 511525.CrossRefGoogle Scholar
Bobylev, A. V. & Potapenko, I. F. 2013 Monte Carlo methods and their analysis for Coulomb collisions in multicomponent plasmas. J. Comput. Phys. 246, 123144.CrossRefGoogle Scholar
Bruno, R. & Carbone, V. 2013 The solar wind as a turbulence laboratory. Living Rev. Sol. Phys. 10, 1208.CrossRefGoogle Scholar
Camporeale, E. & Burgess, D. 2011 The dissipation of solar wind turbulent fluctuations at electron scales. Astrophys. J. 730, 114.CrossRefGoogle Scholar
Chandrasekhar, S. 1956 On force-free magnetic fields. Proc. Natl Acad. Sci. 42, 273.CrossRefGoogle ScholarPubMed
Chapman, S. & Ferraro, V. C. A. 1930 A new theory of magnetic storms. Nature 126 (3169), 129130.CrossRefGoogle Scholar
Chapman, S. & Ferraro, V. C. A. 1931 A new theory of magnetic storms. Terrestrial Magn. Atmos. Electricity 36 (2), 7797.CrossRefGoogle Scholar
Chust, T., Belmont, G., Mottez, F. & Hess, S. 2009 Landau and non-Landau linear damping: physics of the dissipation. Phys. Plasmas 16 (9), 092104.CrossRefGoogle Scholar
Cranmer, S. R., Matthaeus, W. H., Breech, B. A. & Kasper, J. C. 2009 Empirical constraints on proton and electron heating in the fast solar wind. Astrophys. J. 702, 1604.CrossRefGoogle Scholar
Curtis, L. J., Berry, H. G. & Bromander, J. 1970 Analysis of multi-exponential decay curves. Phys. Scr. 2 (4–5), 216.CrossRefGoogle Scholar
Daughton, W., Roytershteyn, V., Albright, B. J., Karimabadi, H., Yin, L. & Bowers, K. J. 2009 Transition from collisional to kinetic regimes in large-scale reconnection layers. Phys. Rev. Lett. 103 (6), 065004.CrossRefGoogle ScholarPubMed
Dobrowolny, M., Mangeney, A. & Veltri, P. 1980a Fully developed anisotropic hydromagnetic turbulence in interplanetary space. Phys. Rev. Lett. 45, 144.CrossRefGoogle Scholar
Dobrowolny, M., Mangeney, A. & Veltri, P. 1980b Properties of magnetohydrodynamic turbulence in the solar wind. In Solar and Interplanetary Dynamics. Springer.Google Scholar
Dougherty, J. K. 1964 Model Fokker–Planck equation for a plasma and its solution. Phys. Fluids 7, 113133.CrossRefGoogle Scholar
Dougherty, J. K. & Watson, S. R. 1967 Model Fokker-Planck equations: part 2. The equation for a multicomponent plasma. J. Plasma Phys. 1, 317326.CrossRefGoogle Scholar
Elsässer, W. M. 1950 The hydromagnetic equations. Phys. Rev. 79, 183.CrossRefGoogle Scholar
Escande, D. F., Elskens, Y. & Doveil, F. 2015 Uniform derivation of Coulomb collisional transport thanks to Debye shielding. J. Plasma Phys. 81 (1), 305810101.CrossRefGoogle Scholar
Filbet, F. & Pareschi, L. 2002 A numerical method for the accurate solution of the Fokker–Planck–Landau equation in the nonhomogeneous case. J. Comput. Phys. 179, 126.CrossRefGoogle Scholar
Franci, L., Verdini, A., Matteini, L., Landi, S. & Hellinger, P. 2015 Solar wind turbulence from MHD to sub-ion scales: high resolution hybrid simulations. Astrophys. J. Lett. 804, L39.CrossRefGoogle Scholar
Frisch, U. P. 1995 Turbulence: the Legacy of A.N. Kolmogorov. Cambridge University Press.CrossRefGoogle Scholar
Gary, S. P. 1993 Theory of Space Plasma Microinstabilities. Cambridge University Press.CrossRefGoogle Scholar
Gary, S. P., Saito, S. & Narita, Y. 2010 Whistler turbulence wavevector anisotropies: particle-in-cell simulations. Astrophys. J. 716, 1332.CrossRefGoogle Scholar
Goldstein, B. E., Neugebauer, M., Phillips, J. L., Bame, S., Gosling, J. T., McComas, D., Wang, Y. M., Sheeley, N. R. & Suess, S. T. 1996 Ulysses plasma parameters: latitudinal, radial and temporal variations. Astron. Astrophys. 316, 296.Google Scholar
Greco, A., Valentini, F., Servidio, S. & Matthaeus, W. H. 2012 Inhomogeneous kinetic effects related to intermittent magnetic discontinuities. Phys. Rev. E 86, 066405.Google ScholarPubMed
He, J., Tu, C., Marsch, E., Chen, C. H. K., Wang, L., Pei, Z., Zhang, L., Salem, C. S. & Bale, S. D. 2015 Proton heating in solar wind compressible turbulence with collisions between counter-propagating waves. Astrophys. J. Lett. 83, L30.CrossRefGoogle Scholar
Hernandez, R. & Marsch, E. 1985 Collisional time scales for temperature and velocity exchange between drifting Maxwellians. J. Geophys. Res. 90 (A11), 1106211066.CrossRefGoogle Scholar
Hirvijoki, E., Lingam, M., Pfefferlé, D., Comisso, L., Candy, J. & Bhattacharjee, A. 2016 Fluid moments of the nonlinear Landau collision operator. Phys. Plasmas 23, 080701.CrossRefGoogle Scholar
Holloway, J. P. & Dorning, J. J. 1991 Undamped plasma waves. Phys. Rev. A 44 (6), 3856.CrossRefGoogle ScholarPubMed
Howes, G. G. & Nielson, K. D. 2013 Alfvén wave collisions, the fundamental building block of plasma turbulence. I. Asymptotic solution. Phys. Plasmas 20, 072302.Google Scholar
Iroshnikov, R. S. 1964 Turbulence of a conducting fluid in a strong magnetic field. Sov. Astron. 7, 566.Google Scholar
Johnston, T. W., Tyshetskiy, Y., Ghizzo, A. & Bertrand, P. 2009 Persistent subplasma-frequency kinetic electrostatic electron nonlinear waves. Phys. Plasmas 16 (4), 042105.CrossRefGoogle Scholar
Kabantsev, A. A., Valentini, F. & Driscoll, C. F. 2006 Experimental investigation of electron-acoustic waves in electron plasmas. Non-Neutral Plasma Phys. VI 862, 1318.Google Scholar
Kasper, J. C., Lazarus, A. J. & Gary, S. P. 2008 Wind/SWE observations of firehose constraint on solar wind proton temperature anisotropy. Geophys. Res. Lett. 29, 20.Google Scholar
Kraichnan, R. H. 1965 Inertialrange spectrum of hydromagnetic turbulence. Phys. Fluids 8, 13851387.CrossRefGoogle Scholar
Landau, L. D. 1936 The transport equation in the case of the coulomb interaction. In Collected papers of L. D. Landau, pp. 163170. Pergamon.Google Scholar
Lenard, A. 1960 On Bogoliubov’s kinetic equation for a spatially homogeneous plasma. Ann. Phys. 10 (3), 390.CrossRefGoogle Scholar
Lesur, M., Diamond, P. H. & Kosuga, Y. 2014 Nonlinear current-driven ion-acoustic instability driven by phase-space structure. Phys. Plasmas 21, 112307.Google Scholar
Livi, S. & Marsch, E. 1986 Comparison of the Bhatnagar–Gross–Krook approximation with the exact Coulomb collision operator. Phys. Rev. A 34, 533540.CrossRefGoogle ScholarPubMed
Lu, Q. M., Wang, D. Y. & Wang, S. 2005 Generation mechanism of electrostatic solitary structures in the Earths auroral region. J. Geophys. Res. 10, A03223.Google Scholar
Marino, R., Sorriso-Valvo, L., Carbone, V., Noullez, A., Bruno, R. & Bavassano, B. 2008 Heating the solar wind by a magnetohydrodynamic turbulent energy cascade. Astrophys. J. Lett. 667, L71L74.CrossRefGoogle Scholar
Marsch, E. 2006 Kinetic physics of the solar corona and solar wind. Living Rev. Sol. Phys. 3, 1100.CrossRefGoogle Scholar
Marsch, E., Muhlhauser, K. H., Schwenn, R., Rosenbauer, H., Pilipp, W. & Neubauer, F. M. 1982 Solar wind protons: three-dimensional velocity distributions and derived plasma parameters measured between 0.3 and 1 AU. J. Geophys. Res. 87, 52.CrossRefGoogle Scholar
Maruca, B. A., Bale, S. D., Sorriso-Valvo, L., Kasper, J. C. & Stevens, M. L. 2013 Collisional thermalization of hydrogen and helium in solar–wind plasma. Phys. Rev. Lett. 111 (24), 241101.CrossRefGoogle ScholarPubMed
Maruca, B. A., Kasper, J. C. & Bale, S. D. 2011 What are the relative roles of heating and cooling in generating solar wind temperature anisotropies? Phys. Rev. Lett. 107, 201101.CrossRefGoogle ScholarPubMed
Matthaeus, W. H., Zank, G. P., Smith, C. W. & Oughton, S. 1999 Turbulence, spatial transport, and heating of the solar wind. Phys. Rev. Lett. 82, 3444.CrossRefGoogle Scholar
Matthaeus, W. H., Dasso, S., Weygand, J. M., Milano, L. J., Smith, C. W. & Kivelson, M. G. 2005 Spatial correlation of solar–wind turbulence from two-point measurements. Phys. Rev. Lett. 95 (23), 231101.CrossRefGoogle ScholarPubMed
Matthaeus, W. H., Oughton, S., Osman, K. T., Servidio, S., Wan, M., Gary, S. P., Shay, M. A., Valentini, F., Roytershteyn, V. & Karimabadi, H. 2014 Nonlinear and linear timescales near kinetic scales in solar wind turbulence. Astrophys. J. 790, 155.CrossRefGoogle Scholar
Matthaeus, W. H., Wan, M., Servidio, S., Greco, A., Osman, K. T., Oughton, S. & Dmitruk, P. 2015 Intermittency, nonlinear dynamics and dissipation in the solar wind and astrophysical plasmas. Phil. Trans. R. Soc. Lond. A 373, 20140154.Google ScholarPubMed
Moffatt, H. K. 1978 Field Generation in Electrically Conducting Fluids. Cambridge University Press.Google Scholar
Ng, C. S. & Bhattacharjee, A. 1996 Interaction of shear-Alfvén wave packets: implication for weak magnetohydrodynamic turbulence in astrophysical plasmas. Astrophys. J. 465, 845.CrossRefGoogle Scholar
Parashar, T. N., Shay, M. A., Cassak, P. A. & Matthaeus, W. H. 2009 Kinetic dissipation and anisotropic heating in a turbulent collisionless plasma. Phys. Plasmas 16, 032310.CrossRefGoogle Scholar
Parker, E. N. 1979 Cosmical Magnetic Fields: Their Origin and Their Activity. Oxford University Press.Google Scholar
Perrone, D., Valentini, F., Servidio, S., Dalena, S. & Veltri, P. 2012 Vlasov simulations of multi-ion plasma turbulence in the solar wind. Astrophys. J. 762, 99.CrossRefGoogle Scholar
Pezzi, O., Valentini, F., Perrone, D. & Veltri, P. 2013 Eulerian simulations of collisional effects on electrostatic plasma waves. Phys. Plasmas 20, 092111.CrossRefGoogle Scholar
Pezzi, O., Valentini, F., Perrone, D. & Veltri, P. 2014 Erratum: Eulerian simulations of collisional effects on electrostatic plasma waves. Phys. Plasmas 21, 019901; Phys. Plasmas 20, 092111 (2013).CrossRefGoogle Scholar
Pezzi, O., Valentini, F. & Veltri, P. 2015a Collisional relaxation: Landau versus Dougherty operator. J. Plasma Phys. 81, 305810107.CrossRefGoogle Scholar
Pezzi, O., Valentini, F. & Veltri, P. 2015b Nonlinear regime of electrostatic waves propagation in presence of electron–electron collisions. Phys. Plasmas 22, 042112.CrossRefGoogle Scholar
Pezzi, O., Valentini, F. & Veltri, P. 2016a Collisional relaxation of fine velocity structures in plasmas. Phys. Rev. Lett. 116, 145001.CrossRefGoogle ScholarPubMed
Pezzi, O., Camporeale, E. & Valentini, F. 2016b Collisional effects on the numerical recurrence in Vlasov–Poisson simulations. Phys. Plasmas 23, 022013.CrossRefGoogle Scholar
Pezzi, O., Parashar, T. N., Servidio, S., Valentini, F., Vásconez, C. L., Yang, Y., Malara, F., Matthaeus, W. H. & Veltri, P. 2017a Revisiting a classic: the Parker–Moffatt problem. Astrophys. J. 834, 166.CrossRefGoogle Scholar
Pezzi, O., Parashar, T. N., Servidio, S., Valentini, F., Vásconez, C. L., Yang, Y., Malara, F., Matthaeus, W. H. & Veltri, P. 2017b Colliding Alfvénic wave packets in magnetohydrodynamics, Hall and kinetic simulations. J. Plasma Phys. 83, 905830105.CrossRefGoogle Scholar
Sahraoui, F., Galtier, S. & Belmont, G. 2007 On waves in incompressible Hall magnetohydrodynamics. J. Plasma Phys. 73, 723730.CrossRefGoogle Scholar
Sahraoui, F., Goldstein, M. E., Robert, P. & Khotyaintsev, Y. V. 2009 Evidence of a cascade and dissipation of solar–wind turbulence at the electron gyroscale. Phys. Rev. Lett. 102, 231102.CrossRefGoogle ScholarPubMed
Servidio, S., Valentini, F., Califano, F. & Veltri, P. 2012 Local kinetic effects in two-dimensional plasma turbulence. Phys. Rev. Lett. 108, 045001.CrossRefGoogle ScholarPubMed
Servidio, S., Valentini, F., Perrone, D., Greco, A., Califano, F., Matthaeus, W. H. & Veltri, P. 2015 A kinetic model of plasma turbulence. J. Plasma Phys. 81, 328510107.CrossRefGoogle Scholar
Sorriso-Valvo, L., Marino, R., Carbone, V., Noullez, A., Lepreti, F., Veltri, P., Bruno, R., Bavassano, B. & Pietropaolo, E. 2007 Observation of inertial energy cascade in interplanetary space plasma. Phys. Rev. Lett. 99, 115001.CrossRefGoogle ScholarPubMed
Spitzer, L. Jr. 1956 Physics of Fully Ionized Gases. Interscience Publishers.Google Scholar
Tigik, S. F., Ziebell, L. F., Yoon, P. H. & Kontar, E. P. 2016 Two-dimensional time evolution of beam-plasma instability in the presence of binary collisions. Astron. Astrophys. 586, A19.CrossRefGoogle Scholar
Tokar, R. L. & Gary, S. P. 1984 Electrostatic hiss and the beam driven electron acoustic instability in the dayside polar cusp. Geophys. Res. Lett. 11, 11801183.CrossRefGoogle Scholar
Vaivads, A., Retinó, A., Soucek, J., Khotyaintsev, Yu. V., Valentini, F., Escoubet, C. P., Alexandrova, O., André, M., Bale, S. D., Balikhin, M. et al. 2016 Turbulence heating ObserveR – satellite mission proposal. J. Plasma Phys. 82, 905820501.CrossRefGoogle Scholar
Valentini, F., Carbone, V., Veltri, P. & Mangeney, A. 2005 Self-consistent Lagrangian study of nonlinear Landau damping. Phys. Rev. E 71, 017402.Google ScholarPubMed
Valentini, F., Califano, F., Perrone, D., Pegoraro, F. & Veltri, P. 2011a New ion-wave path in the energy cascade. Phys. Rev. Lett. 106, 165002.CrossRefGoogle ScholarPubMed
Valentini, F., Perrone, D. & Veltri, P. 2011b Short-wavelength electrostatic fluctuations in the solar wind. Astrophys. J. 739, 54.CrossRefGoogle Scholar
Valentini, F., ONeil, T. M. & Dubin, D. H. E. 2006 Excitation of nonlinear electron acoustic waves. Phys. Plasmas 13 (5), 052303.CrossRefGoogle Scholar
Valentini, F., Perrone, D., Califano, F., Pegoraro, F., Veltri, P., Morrison, P. J. & O’Neil, T. M. 2012 Undamped electrostatic plasma waves. Phys. Plasmas 20, 034701.Google Scholar
Valentini, F., Perrone, D., Stabile, S., Pezzi, O., Servidio, S., De Marco, R. & Consolini, G. 2016 Differential kinetic dynamics and heating of ions in the turbulent solar wind. New J. Phys. 18 (12), 125001.CrossRefGoogle Scholar
Valentini, F., Servidio, S., Perrone, D., Califano, F., Matthaeus, W. H. & Veltri, P. 2014 Hybrid Vlasov–Maxwell simulations of two-dimensional turbulence in plasmas. Phys. Plasmas 21, 082307.CrossRefGoogle Scholar
Valentini, F., Travnicek, P., Califano, F., Hellinger, P. & Mangeney, A. 2007 A hybrid-Vlasov model based on the current advance method for the simulation of collisionless magnetized plasma. J. Comput. Phys. 225, 753770.CrossRefGoogle Scholar
Verdini, A., Velli, M. & Buchlin, E. 2009 Turbulence in the sub-Alfvénic solar wind driven by reflection of low-frequency Alfvén waves. Astrophys. J. Lett. 700, L39.CrossRefGoogle Scholar
Villani, C. 2002 Handbook of Mathematical Fluid Dynamics, A Review of Mathematical Topics in Collisional Kinetic Theory, vol. 1, pp. 71305.CrossRefGoogle Scholar
Watanabe, K. & Taniuti, T. 1977 Electron-acoustic mode in a plasma of two-temperature electrons. J. Phys. Soc. Japan 43, 1819.CrossRefGoogle Scholar
Figure 0

Figure 1. (a) Power spectral density of the electric energy $E_{E}(k_{z})$ as a function of the wavenumber $k_{z}$. (b) Contour plot of $f_{e}(z,v_{z})$ at the time instant when the EAWs is fully developed. The red line represents the coordinate $z=z_{0}$ where the cut is performed. (c) Profile of $f_{e}(z_{0},v_{z})$ as a function of $v_{z}$.

Figure 1

Figure 2. Time history of $\unicode[STIX]{x0394}S$ in the case of the fully nonlinear Landau operator (black) and the linearized Landau operator (red). Blue diamonds indicate the time instants $t=T_{nl,1}=\unicode[STIX]{x1D70F}_{1}^{nl}$, $t=T_{nl,2}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}$ and $t=T_{nl,3}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}+\unicode[STIX]{x1D70F}_{3}^{nl}$; the green triangles refer to $t=T_{lin,1}=\unicode[STIX]{x1D70F}_{1}^{lin}$, $t=T_{lin,2}=\unicode[STIX]{x1D70F}_{1}^{lin}+\unicode[STIX]{x1D70F}_{2}^{lin}$ and $t=T_{lin,3}=\unicode[STIX]{x1D70F}_{1}^{lin}+\unicode[STIX]{x1D70F}_{2}^{lin}+\unicode[STIX]{x1D70F}_{3}^{lin}$.

Figure 2

Figure 3. Distribution function $f(v_{x}=0,v_{y}=0,v_{z})$ as a function of $v_{z}$, obtained in the case of the fully nonlinear Landau operator. Panels from (a) to (d) respectively display the time instants $t=T_{nl,1}=\unicode[STIX]{x1D70F}_{1}^{nl}$ (a), $t=T_{nl,2}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}$ (b), $t=T_{nl,3}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}+\unicode[STIX]{x1D70F}_{3}^{nl}$ (c) and $t=t_{fin}$ (d). Results for the linearized Landau operator are qualitatively the same with the primary difference being that $\unicode[STIX]{x1D70F}_{j}^{nl}$ is substantially smaller than $\unicode[STIX]{x1D70F}_{j}^{lin}$ for each value of $j$.

Figure 3

Figure 4. (a) Omni-directional power spectral densities (PSDs) of the magnetic energy $E_{B}(k_{\bot })$ (black line) and of the electric energy $E_{E}(k_{\bot })$ (red line) as a function of the perpendicular wavenumber $k_{\bot }$. PSDs have been evaluated at the time instant where the turbulent activity is maximum. (b) Iso-surface of the initial distribution function. Red, green and blue axes refer to $v_{x}$, $v_{y}$ and $v_{z}$, respectively.

Figure 4

Figure 5. Time history of $\unicode[STIX]{x0394}S$ in the case of the fully nonlinear Landau operator (black) and the linearized Landau operator (red). Blue diamonds indicate the time instants $t=T_{nl,1}=\unicode[STIX]{x1D70F}_{1}^{nl}$ and $t=T_{nl,2}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}$; the green triangles refer to $t=T_{lin,1}=\unicode[STIX]{x1D70F}_{1}^{lin}$ and $t=T_{lin,2}=\unicode[STIX]{x1D70F}_{1}^{lin}+\unicode[STIX]{x1D70F}_{2}^{lin}$.

Figure 5

Figure 6. Iso-surface of the distribution function, obtained in the case of the fully nonlinear Landau operator. Panels (a) and (b) respectively display the time instants $t=T_{nl,1}=\unicode[STIX]{x1D70F}_{1}^{nl}$ and $t=T_{nl,2}=\unicode[STIX]{x1D70F}_{1}^{nl}+\unicode[STIX]{x1D70F}_{2}^{nl}$. Red, green and blue axes refer to $v_{x}$, $v_{y}$ and $v_{z}$, respectively. The results for the linearized Landau operator are qualitatively the same with the primary difference being that $\unicode[STIX]{x1D70F}_{j}^{nl}$ is substantially smaller than $\unicode[STIX]{x1D70F}_{j}^{lin}$ for each value of $j$.