Your search keyword '"Cranmer, Steven R"' showing total 9 results

1. Self-Consistent Models of the Solar Wind

Author

Cranmer, Steven R.

Published

2012

2. Turbulent Generation of Magnetic Switchbacks in the Alfvénic Solar Wind.

Author

Shoda, Munehito, Chandran, Benjamin D. G., and Cranmer, Steven R.

Subjects

SOLAR wind, PLASMA Alfven waves, SOLAR corona, MAGNETOHYDRODYNAMICS, TURBULENCE, COMPRESSIBILITY

Abstract

One of the most important early results from the Parker Solar Probe (PSP) is the ubiquitous presence of magnetic switchbacks, whose origin is under debate. Using a three-dimensional direct numerical simulation of the equations of compressible magnetohydrodynamics from the corona to 40 solar radii, we investigate whether magnetic switchbacks emerge from granulation-driven Alfvén waves and turbulence in the solar wind. The simulated solar wind is an Alfvénic slow-solar-wind stream with a radial profile consistent with various observations, including observations from PSP. As a natural consequence of Alfvén-wave turbulence, the simulation reproduced magnetic switchbacks with many of the same properties as observed switchbacks, including Alfvénic v–b correlation, spherical polarization (low magnetic compressibility), and a volume filling fraction that increases with radial distance. The analysis of propagation speed and scale length shows that the magnetic switchbacks are large-amplitude (nonlinear) Alfvén waves with discontinuities in the magnetic-field direction. We directly compare our simulation with observations using a virtual flyby of PSP in our simulation domain. We conclude that at least some of the switchbacks observed by PSP are a natural consequence of the growth in amplitude of spherically polarized Alfvén waves as they propagate away from the Sun. [ABSTRACT FROM AUTHOR]

Published

2021

3. Heating of the solar wind with electron and proton effects.

Author

Breech, Ben, Cranmer, Steven R., Matthaeus, William H., Kasper, Justin C., and Oughton, Sean

Subjects

*SOLAR wind, *SOLAR corona, *SOLAR activity, *STELLAR winds, *PROTONS, *ELECTRONS

Abstract

We examine the effects of including effects of both protons and electrons on the heating of the fast solar wind through two different approaches. In the first approach, we incorporate the electron temperature in an MHD turbulence transport model for the solar wind. In the second approach, we adopt more empirically based methods by analyzing the measured proton and electron temperatures to calculate the heat deposition rates. Overall, we conclude that incorporating separate proton and electron temperatures and heat conduction effects provides an improved and more complete model of the heating of the solar wind. [ABSTRACT FROM AUTHOR]

Published

2010

4. Accretion-driven winds of T Tauri stars: A new generation of models with self-consistent coronal heating and MHD turbulence.

Author

Cranmer, Steven R.

Subjects

*STARS, *ACCRETION (Astrophysics), *TURBULENCE, *STELLAR winds, *ANGULAR momentum (Mechanics)

Abstract

Classical T Tauri stars are observed to be surrounded by both accretion flows and some kind of wind or jet-like outflow. There are several possible explanations of how and where the outflows arise, including disk winds, X-winds, impulsive (CME-like) ejections, and stellar winds. Recent work by Matt and Pudritz has suggested that if there is a stellar wind with a mass loss rate about 0.1 times the accretion rate, the wind may be able to carry away enough angular momentum to keep the stars from being spun up unrealistically by accretion. In this presentation, I show a preliminary set of theoretical models of accretion-driven winds from the polar regions of T Tauri stars. These models are based on recently published self-consistent simulations of the Sun’s coronal heating and wind acceleration. In addition to the convection-driven MHD turbulence (which dominates in the solar case), I add a source of wave energy at the photosphere that is driven by the impact of plasma in neighboring flux tubes undergoing magnetospheric accretion. This added energy, which is determined quantitatively from the far-field theory of MHD wave generation, seems to be enough to produce T Tauri-like mass loss rates. It is still uncertain, though, whether it is enough to solve the T Tauri angular momentum problem. [ABSTRACT FROM AUTHOR]

Published

2009

5. CONSTRAINING A MODEL OF TURBULENT CORONAL HEATING FOR AU MICROSCOPII WITH X-RAY, RADIO, AND MILLIMETER OBSERVATIONS.

Author

CRANMER, STEVEN R., WILNER, DAVID J., and MACGREGOR, MEREDITH A.

Subjects

*LOW mass stars, *DWARF stars, *ACCRETION disks, *COSMIC dust, *SIMULATION methods & models, *SOLAR x-rays, MAGNETIC fields in the solar corona

Abstract

Many low-mass pre-main-sequence stars exhibit strong magnetic activity and coronal X-ray emission. Even after the primordial accretion disk has been cleared out, the star's high-energy radiation continues to affect the formation and evolution of dust, planetesimals, and large planets. Young stars with debris disks are thus ideal environments for studying the earliest stages of non-accretion-driven coronae. In this paper we simulate the corona of AU Mic, a nearby active M dwarf with an edge-on debris disk. We apply a self-consistent model of coronal loop heating that was derived from numerical simulations of solar field-line tangling and magnetohydrodynamic turbulence.We also synthesize the modeled star's X-ray luminosity and thermal radio/millimeter continuum emission. A realistic set of parameter choices for AU Mic produces simulated observations that agree with all existing measurements and upper limits. This coronal model thus represents an alternative explanation for a recently discovered ALMA central emission peak that was suggested to be the result of an inner "asteroid belt" within 3 AU of the star. However, it is also possible that the central 1.3 mm peak is caused by a combination of active coronal emission and a bright inner source of dusty debris. Additional observations of this source's spatial extent and spectral energy distribution at millimeter and radio wavelengths will better constrain the relative contributions of the proposed mechanisms. [ABSTRACT FROM AUTHOR]

Published

2013

6. CONNECTING THE SUN'S HIGH-RESOLUTION MAGNETIC CARPET TO THE TURBULENT HELIOSPHERE.

Author

CRANMER, STEVEN R., VAN BALLEGOOIJEN, ADRIAAN A., and WOOLSEY, LAUREN N.

Subjects

*HELIOSPHERE, *HELIOSPHERE (Ionosphere), *ENERGY conservation, *CORONA discharge, *SOLAR photosphere, *STELLAR photospheres

Abstract

The solar wind is connected to the Sun's atmosphere by flux tubes that are rooted in an ever-changing pattern of positive and negative magnetic polarities on the surface. Observations indicate that the magnetic field is filamentary and intermittent across a wide range of spatial scales. However, we do not know towhat extent the complex flux-tube topology seen near the Sun survives as the wind expands into interplanetary space. In order to study the possible long-distance connections between the corona and the heliosphere, we developed new models of turbulence-driven solar wind acceleration along empirically constrained field lines. We used a potential field model of the quiet Sun to trace field lines into the ecliptic plane with unprecedented spatial resolution at their footpoints. For each flux tube, a one-dimensional model was created with an existing wave/turbulence code that solves equations of mass, momentum, and energy conservation from the photosphere to 4 AU. To take account of stream-stream interactions between flux tubes, we used those models as inner boundary conditions for a time-steady magnetohydrodynamic description of radial and longitudinal structure in the ecliptic. Corotating stream interactions smear out much of the smallest-scale variability, making it difficult to see how individual flux tubes on granular or supergranular scales can survive out to 1 AU. However, our models help clarify the level of "background" variability with which waves and turbulent eddies should be expected to interact. Also, the modeled fluctuations in magnetic field magnitude were seen to match measured power spectra quite well. [ABSTRACT FROM AUTHOR]

Published

2013

7. TESTING A PREDICTIVE THEORETICAL MODEL FOR THE MASS LOSS RATES OF COOL STARS.

Author

CRANMER, STEVEN R. and SAAR, STEVEN H.

Subjects

*COOL stars (Astronomy), *STELLAR mass, *SOLAR wind, *MAGNETOHYDRODYNAMICS, *TURBULENCE, *MAGNETIC fields

Abstract

The basic mechanisms responsible for producing winds from cool, late-type stars are still largely unknown. We take inspiration from recent progress in understanding solar wind acceleration to develop a physically motivated model of the time-steady mass loss rates of cool main-sequence stars and evolved giants. This model follows the energy flux of magnetohydrodynamic turbulence from a subsurface convection zone to its eventual dissipation and escape through open magnetic flux tubes. We show how Alfvén waves and turbulence can produce winds in either a hot corona or a cool extended chromosphere, and we specify the conditions that determine whether or not coronal heating occurs. These models do not utilize arbitrary normalization factors, but instead predict the mass loss rate directly from a star's fundamental properties. We take account of stellar magnetic activity by extending standard age-activity-rotation indicators to include the evolution of the filling factor of strong photospheric magnetic fields. We compared the predicted mass loss rates with observed values for 47 stars and found significantly better agreement than was obtained from the popular scaling laws of Reimers, Schröder, and Cuntz. The algorithm used to compute cool-star mass loss rates is provided as a self-contained and efficient computer code. We anticipate that the results from this kind of model can be incorporated straightforwardly into stellar evolution calculations and population synthesis techniques. [ABSTRACT FROM AUTHOR]

Published

2011

8. The role of turbulence in coronal heating and solar wind expansion.

Author

Cranmer, Steven R., Asgari-Targhi, Mahboubeh, Miralles, Mari Paz, Raymond, John C., Strachan, Leonard, Hui Tian, and Woolsey, Lauren N.

Subjects

*SOLAR corona, *SOLAR wind, *MAGNETOHYDRODYNAMICS, *TURBULENCE, *MAGNETIC reconnection, *ULTRAVIOLET spectroscopy

Abstract

Plasma in the Sun's hot corona expands into the heliosphere as a supersonic and highly magnetized solar wind. This paper provides an overview of our current understanding of how the corona is heated and how the solar wind is accelerated. Recent models of magnetohydrodynamic turbulence have progressed to the point of successfully predicting many observed properties of this complex, multi-scale system. However, it is not clear whether the heating in open-field regions comes mainly from the dissipation of turbulent fluctuations that are launched from the solar surface, or whether the chaotic 'magnetic carpet' in the low corona energizes the system via magnetic reconnection. To help pin down the physics, we also review some key observational results from ultraviolet spectroscopy of the collisionless outer corona. [ABSTRACT FROM AUTHOR]

Published

2015

9. Compressible Aspects of Slow Solar Wind Formation

Author

Dahlburg, R. B., Einaudi, G., Kohl, John L., editor, and Cranmer, Steven R., editor

Published

1999