A journey of exploration to the polar regions of a star: probing the solar poles and the heliosphere from high helio-latitude

TL;DR

A proposed mission aims to explore the solar poles from high helio-latitudes, addressing key mysteries of the solar cycle and enabling unique studies of solar phenomena and their impacts on space weather and Earth's climate.

Contribution

This paper introduces a novel mission concept focused on observing the solar poles from above, providing insights unattainable by current missions and advancing understanding of solar activity and space weather.

Findings

Enhanced understanding of solar polar regions

New insights into the solar cycle and activity

Potential improvements in space weather prediction

Abstract

A mission to view the solar poles from high helio-latitudes (above 60$^\circ$) will build on the experience of Solar Orbiter as well as a long heritage of successful solar missions and instrumentation (e.g. SOHO \cite{SOHO}, STEREO \cite{stereo}, Hinode \cite{Hinode}, SDO \cite{SDO}), but will focus for the first time on the solar poles, enabling scientific investigations that cannot be done by any other mission. One of the major mysteries of the Sun is the solar cycle. The activity cycle of the Sun drives the structure and behaviour of the heliosphere and is, of course, the driver of space weather. In addition, solar activity and variability provides fluctuating input into the Earth climate models, and these same physical processes are applicable to stellar systems hosting exoplanets. One of the main obstructions to understanding the solar cycle, and hence all solar activity, is our current lack of understanding of the polar regions. In this White Paper, submitted to the European Space Agency in response to the Voyage 2050 call, we describe a mission concept that aims to address this fundamental issue. In parallel, we recognise that viewing the Sun from above the polar regions enables further scientific advantages, beyond those related to the solar cycle, such as unique and powerful studies of coronal mass ejection processes, from a global perspective, and studies of coronal structure and activity in polar regions. Not only will these provide important scientific advances for fundamental stellar physics research, they will feed into our understanding of impacts on the Earth and other planets' space environment.