The lepton number violating process of neutrinoless double-beta decay could result from the physics beyond the Standard Model needed to generate the neutrino masses. Taking different approaches, the current generation of $^{76}$Ge experiments, the MAJORANA DEMONSTRATOR and GERDA, lead the field in both the ultra-low background and energy resolution achieved. The next generation of neutrinoless double-beta decay experiments requires increased mass and further reduction of backgrounds to maximize discovery potential. Building on the successes of the MAJORANA DEMONSTRATOR and GERDA, the LEGEND collaboration has been formed to pursue a tonne-scale $^{76}$Ge experiment, with discovery potential at a half-life beyond $10^{28}$ years. The collaboration aims to develop a phased neutrinoless double-beta decay experimental program, starting with a 200 kg measurement using the existing GERDA cryostat at LNGS. These proceedings discuss the plans and physics reach of LEGEND, and the combination of R&D efforts and existing resources being employed to expedite physics results.
[1]
S. Schönert,et al.
Virtual depth by active background suppression: revisiting the cosmic muon induced background of Gerda Phase II
,
2018,
The European Physical Journal C.
[2]
M. Agostini,et al.
Discovery probability of next-generation neutrinoless double- β decay experiments
,
2017,
1705.02996.
[3]
J. C. Loach,et al.
The Majorana Demonstrator Radioassay Program
,
2016,
1601.03779.
[4]
K. Vetter,et al.
The {\sc Majorana Demonstrator} Neutrinoless Double-Beta Decay Experiment
,
2013,
1308.1633.
[5]
C. A. Ur,et al.
The Gerda experiment for the search of 0νββ decay in 76Ge
,
2012,
1212.4067.
[6]
W. Rodejohann.
NEUTRINO-LESS DOUBLE BETA DECAY AND PARTICLE PHYSICS
,
2011,
1106.1334.