%0 Generic %1 citeulike:12944430 %A Miesch, Mark S. %A Dikpati, Mausumi %D 2014 %K imported %T A 3D Babcock-Leighton Solar Dynamo Model %U http://arxiv.org/abs/1401.6557 %X We present a 3D kinematic solar dynamo model in which poloidal field is generated by the emergence and dispersal of tilted sunspot pairs (more generally Bipolar Magnetic Regions, or BMRs). The axisymmetric component of this model functions similarly to previous 2D Babcock-Leighton (BL) dynamo models that employ a double-ring prescription for poloidal field generation but we generalize this prescription into a 3D flux emergence algorithm that places BMRs on the surface in response to the dynamo-generated toroidal field. In this way, the model can be regarded as a unification of BL dynamo models (2D in radius/latitude) and surface flux transport models (2D in latitude/longitude) into a more self-consistent framework that captures the full 3D structure of the evolving magnetic field. The model reproduces some basic features of the solar cycle including an 11-yr periodicity, equatorward migration of toroidal flux in the deep convection zone, and poleward propagation of poloidal flux at the surface. The poleward-propagating surface flux originates as trailing flux in BMRs, migrates poleward in multiple non-axisymmetric streams (made axisymmetric by differential rotation and turbulent diffusion), and eventually reverses the polar field, thus sustaining the dynamo. In this letter we briefly describe the model, initial results, and future plans.

@misc{citeulike:12944430, abstract = {{We present a 3D kinematic solar dynamo model in which poloidal field is generated by the emergence and dispersal of tilted sunspot pairs (more generally Bipolar Magnetic Regions, or BMRs). The axisymmetric component of this model functions similarly to previous 2D Babcock-Leighton (BL) dynamo models that employ a double-ring prescription for poloidal field generation but we generalize this prescription into a 3D flux emergence algorithm that places BMRs on the surface in response to the dynamo-generated toroidal field. In this way, the model can be regarded as a unification of BL dynamo models (2D in radius/latitude) and surface flux transport models (2D in latitude/longitude) into a more self-consistent framework that captures the full 3D structure of the evolving magnetic field. The model reproduces some basic features of the solar cycle including an 11-yr periodicity, equatorward migration of toroidal flux in the deep convection zone, and poleward propagation of poloidal flux at the surface. The poleward-propagating surface flux originates as trailing flux in BMRs, migrates poleward in multiple non-axisymmetric streams (made axisymmetric by differential rotation and turbulent diffusion), and eventually reverses the polar field, thus sustaining the dynamo. In this letter we briefly describe the model, initial results, and future plans.}}, added-at = {2019-03-25T08:20:55.000+0100}, archiveprefix = {arXiv}, author = {Miesch, Mark S. and Dikpati, Mausumi}, biburl = {https://www.bibsonomy.org/bibtex/24f7c657385d8f610b6bd71edf5f3692a/ericblackman}, citeulike-article-id = {12944430}, citeulike-linkout-0 = {http://arxiv.org/abs/1401.6557}, citeulike-linkout-1 = {http://arxiv.org/pdf/1401.6557}, day = 25, eprint = {1401.6557}, interhash = {94b659360cc5aa8c02d5f99d3811077f}, intrahash = {4f7c657385d8f610b6bd71edf5f3692a}, keywords = {imported}, month = jan, posted-at = {2014-02-02 04:34:08}, priority = {2}, timestamp = {2019-03-25T08:20:55.000+0100}, title = {{A 3D Babcock-Leighton Solar Dynamo Model}}, url = {http://arxiv.org/abs/1401.6557}, year = 2014 }