The present invention relates to a lamp having synthetic ceramic glass electrodes, which comprises a glass tube, a plurality of synthetic ceramic glass electrodes, and a plurality of connecting members. The plurality of connecting members are disposed between the glass tube and the plurality of synthetic ceramic glass electrodes. The plurality of connecting members have different thermal expansion coefficients. Thereby, by using the plurality of connecting members to connect the plurality of synthetic ceramic glass electrodes, the glass tube and the plurality of synthetic ceramic glass electrodes can be sealed tightly.

The present disclosure relates to a far ultraviolet light emitting device and a home appliance having the same. The present disclosure may include a first electrode part 130A and a second electrode part 130B spaced apart from the first electrode part 130A. A barrier may be arranged between the first electrode part 130A and the second electrode part 130B. An ultraviolet lamp 140 may have an electrode connection surface 141B arranged toward the surface of the first electrode part 130A, the surface of the second electrode part 130B, and the surface of the barrier 126, and a light extraction surface 141A arranged toward the opposite side of the electrode connection surface 141B. In this case, at least one of the surfaces of the first electrode part 130A or second electrode part 130B and the surface of the barrier 126 may be spaced apart from each other to form a gap part 136. The gap part 136 may be opened toward the electrode connection surface 141B.

The present disclosure relates to a far ultraviolet light emitting device and a home appliance having the same. The present disclosure may include a first electrode part 130A and a second electrode part 130B spaced apart from the first electrode part 130A. A barrier may be arranged between the first electrode part 130A and the second electrode part 130B. An ultraviolet lamp 140 may have an electrode connection surface 141B arranged toward the surface of the first electrode part 130A, the surface of the second electrode part 130B, and the surface of the barrier 126, and a light extraction surface 141A arranged toward the opposite side of the electrode connection surface 141B. In this case, at least one of the surfaces of the first electrode part 130A or second electrode part 130B and the surface of the barrier 126 may be spaced apart from each other to form a gap part 136. The gap part 136 may be opened toward the electrode connection surface 141B.