Current-independent　metal　transfer,　in　free-flight　or　short-circuiting　mode,　was　previously　achieved　by　utilizing　single-side　pulsed　laser　irradiation　on　the　droplet.　However,　the　droplet　was　always　detached　with　a　deflection　approximately　along　the　laser　incident　direction,　but　not　in　the　wire　axial　way　as　generally　expected.　The　droplet　deflection　also　acts　as　a　cushion　to　the　laser　impulse.　Hence,　the　double-sided　pulsed-laser-driven　metal　transfer　is　studied　by　comparing　it　with　that　of　non-laser　and　single　laser　enhanced　metal　transfer　in　this　paper.　The　results　demonstrate　that　double-sided　laser　irradiation　leads　to　a　significant　increase　in　the　transfer　frequency　and　process　stability.　Differing　from　the　way　of　droplet　deflection　driven　by　single　laser　irradiation,　double-sided　symmetrical　laser　irradiation　with　the　same　laser　pulse　parameters　results　in　wire-axial　metal　transfer　of　higher　frequency,　either　in　drop　spray　or　short-circuiting　transfer　mode,　depending　on　the　arc　length.　Moreover,　the　dual　laser　irradiation　contributes　considerably　to　melt　the　wire　when　the　current　is　ultra-low.　The　wire　tip　was　even　shaped　to　a　pencil-like　profile　by　the　lasers,　similar　to　that　of　traditional　stream　spray　transfer　in　high-current　GMAW,　which　facilitates　the　co-axial　metal　transfer.　The　transfer　frequency　of　short-circuiting　transfer　and　drop　spray　transfer　under　80A　current　is　up　to100　Hz　and　150　Hz　(0.8　mm　wire　diameter,　pure　argon　shielding　gas),　respectively.　Even　the　current　is　as　low　as　40　A,　the　drop　spray　transfer　frequency　can　still　be　up　to　100　Hz.