Neutrino oscillation KamLAND started to collect data on January 17, 2002. First results were reported using only 145 days of data. Without
neutrino oscillation, events were expected, however, only 54 events were observed. KamLAND confirmed this result with a 515-day data sample, 365.2 events were predicted in the absence of oscillation, and 258 events were observed. These results established antineutrino disappearance at high significance. The KamLAND detector not only counts the antineutrino rate, but also measures their energy. The shape of this energy spectrum carries additional information that can be used to investigate neutrino oscillation hypotheses. Statistical analyses in 2005 show the spectrum distortion is inconsistent with the no-oscillation hypothesis and two alternative disappearance mechanisms, namely the neutrino decay and de-coherence models. It is consistent with 2-neutrino oscillation and a fit provides the values for the Δm2 and θ parameters. Since KamLAND measures Δm2 most precisely and the solar experiments exceed KamLAND's ability to measure θ, the most precise oscillation parameters are obtained in combination with solar results. Such a combined fit gives \Delta{m^2} = 7.9^{+0.6}_{-0.5} \cdot 10^{-5} \text{eV}^2 and \tan^2\theta = 0.40^{+0.10}_{-0.07} , the best neutrino oscillation parameter determination to that date. Since then a 3 neutrino model has been used. Precision combined measurements were reported in 2008 and 2011: :\Delta m_{21}^2 = 7.59 \pm 0.21 \cdot 10^{-5} \, \text{eV}^2,\,\, \tan^2 \theta _{12} = 0.47^{+0.06}_{-0.05}
Geological antineutrinos (geoneutrinos) KamLAND also published an investigation of geologically-produced antineutrinos (so-called
geoneutrinos) in 2005. These neutrinos are produced in the decay of
thorium and
uranium in the Earth's
crust and
mantle. A few geoneutrinos were detected and these limited data were used to limit the U/Th radiopower to under 60TW. Combination results with Borexino were published in 2011, measuring the U/Th heat flux. New results in 2013, benefiting from the reduced backgrounds due to Japanese reactor shutdowns, were able to constrain U/Th radiogenic heat production to 11.2^{+7.9}_{-5.1} TW using 116 \bar{\nu}_e events. This constrains composition models of the bulk silicate Earth and agrees with the reference Earth model.
KamLAND-Zen Double Beta Decay Search KamLAND-Zen uses the detector to study beta decay of 136Xe from a balloon placed in the scintillator in summer 2011. Observations set a limit for neutrinoless double-beta decay half-life of . A double beta decay lifetime was also measured: 2.38 \pm{0.02(\mathrm{stat})} \pm{0.14(\mathrm{syst})} *10^{21} yr, consistent with other xenon studies. KamLAND-Zen plans continued observations with more enriched Xe and improved detector components. An improved search was published in August 2016, increasing the half-life limit to , with a neutrino mass bound of 61–165 meV. The first KamLAND-Zen apparatus,
KamLAND-Zen 400, completed two research programs, Phase I (2011 Oct. - 2012 Jun.) and Phase II (2013 Dec. - 2015 Oct.). The combined data of Phase I and II implied the lower bound 1.07 \times 10^{26} years for the neutrinoless double beta decay half-life. The KamLAND-Zen 400 operated from 2011 October to 2015 October and was then replaced by KamLAND-Zen 800. The second KamLAND-Zen experiment apparatus,
KamLAND-Zen 800, with bigger balloon of about 750 kg of Xenon was installed in the KamLAND detector 10 May 2018. The operation was expected to start winter 2018-2019 with 5 years of expected operation. The KamLAND-Zen 800 experiment started data taking in January 2019 and first results were published in 2020. In January 2023, the KamLAND-Zen Collaboration using the KamLAND-Zen 800 published results about neutrinoless double-beta decay in Xe-136 using data collected between February 5, 2019 and May 8, 2021. No neutrinoless double-beta decay was observed, and the established lower bound for half-life was T > 2.3 \times 10^{26} yr corresponding to upper limits on the effective Majorana neutrino mass of 36–156 meV. Further results published in December 2025 increase the half-life lower bound to T > 3.8 \times 10^{26} yr, corresponding to a mass of 28–122 meV. The KamLAND-Zen collaboration is planning to construct another apparatus,
KamLAND2-Zen in the long term. ==References==