Introduction

Neutrinos, the products of radioactive decay among other things, are somewhat enigmatic, since they can travel enormous distances through matter without interacting even once. Understanding their properties in detail is fundamentally important. Notwithstanding that they are so very difficult to observe, great progress in this field has been achieved in recent decades. The study of neutrinos is opening a path for the generalization of the so-called Standard Model that explains most of what we know about elementary particles and their interactions, but in the view of most physicists is incomplete.

The Standard Model of electroweak interactions, developed in late 1960s, incorporates neutrinos (νe, νμ, ντ) as left-handed partners of the three families of charged leptons (e, μ, τ). Since weak interactions are the only way neutrinos interact with anything, the un-needed right-handed components of the neutrino field are absent in the Model by definition and neutrinos are assumed to be massless, with the individual lepton number (that is, the number of leptons of a given flavour or family) being strictly conserved. This assignment was supported by the lack of observation of decays like or , despite the long search for them.

The discovery of neutrino oscillations over the past several decades proved that these assumptions were incorrect. That discovery represents one of the very few instances that show that the Standard Model is indeed incomplete. The phenomenon of neutrino oscillations means that neutrinos have a finite mass, albeit very small, and that lepton flavour is not a conserved quantity. Box 1 explains the basic physics of neutrino oscillations and their relation with neutrino masses, and introduces the parameters used in the oscillation formalism. Determination of all their values, with ever increasing accuracy, was and continues to be the main goal of neutrino experiments. The current experimental values of the mass-squared differences and the mixing angles θij can be found in the latest editions of the Review of Particle Physics1 and is also shown in Box 1. Historically, the concept of neutrino oscillations was first considered by Pontecorvo2,3 and by Maki, Nakagawa and Sakata4, hence the neutrino mixing matrix is usually called the PMNS matrix.

The study of reactor neutrinos played a very significant part in the discovery and detailed study of neutrino oscillations and will continue to be essential to its further progress. Here we briefly review the main points of this saga. Figure 1 illustrates how the flavour composition of the reactor neutrino flux, starting as pure at production (see the next section for details), is expected to oscillate as a function of distance. Experimental verification of this behaviour, and quantitative analysis of the results, are the main topics discussed below.

Figure 1: Illustration of neutrino oscillations.
figure 1

The expected flavour composition of the reactor neutrino flux, for neutrinos of 4 MeV energy used as an example, is plotted as a function of distance to the reactor cores. The fraction of neutrino flavours is calculated on the basis of the neutrino oscillation theory introduced in Box 1. Reactor neutrino oscillation experiments are placed at different baselines to measure the oscillation features driven by different mechanisms. The experiments are usually categorized as follows: very short-baseline (L10 m); short-baseline (L100 m); kilometre-baseline (L1 km); medium-baseline (L50 km); and long-baseline (L>100 km) experiments. Details of the past and future reactor experiments, their goals and achievements are the main topics of this Review.

The existence of neutrinos was predicted by Pauli already in 1930 (ref. 5) in his famous letter attempting to explain the continuous electron energy distribution in nuclear beta decay. However, it was not until 1953–1959 that Reines and Cowan6,7,8 were able to show that neutrinos were real particles. Their observation used the electron antineutrinos emitted by a nuclear reactor and started a long tradition of fundamental discoveries using reactor ’s.

In the early experiments, detectors were placed at distances L≤100 m (refs 9, 10, 11, 12, 13, 14, 15; for a review see ref. 16). These pioneering short-baseline experiments, in agreement with the later established three-neutrino oscillation theory, did not observe variations with distance; however, they were important for the understanding of the reactor neutrino flux and spectrum. The KamLAND experiment17,18,19 in the 2000s convincingly showed that the earlier solar neutrino measurements were indeed caused by oscillations. It demonstrated for the first time that the reactor neutrinos indeed oscillate, that is, that the component changes with L/Eν, as explained in Box 1. It also allowed the most accurate determination of the mass-squared difference .

In the next generation of reactor experiments including Daya Bay20,21, RENO22 and Double Chooz23,24, the longstanding puzzle of the value of the mixing angle θ13 was successfully resolved; it turns out that its value θ138.9° (or sin2 2θ13=0.093 (ref. 1)) is not as small as many physicists expected. That discovery opened opportunities for further experiments that should eventually let us determine the so-far missing fundamental features of the oscillations, the neutrino mass hierarchy (MH) and the phase δCP that characterizes the possible CP (charge and parity) violation. The planned reactor experiments, JUNO25 and RENO-50 (ref. 26), promise to be an important step on this path.

Most of the oscillation results are well described by the simple three-neutrino generation hypothesis. However, there are a few anomalous indications, the so-called reactor antineutrino anomaly27 among them, that cannot be explained this way. If confirmed, they would indicate the existence of additional fourth, or fifth, and so on neutrino families called sterile neutrinos. These neutrinos lack weak interactions and would be observable only when mixing with the familiar active neutrinos. The proposed very short-baseline reactor experiments at distances 10 m will test whether this fascinating possibility is realistic or not.

The discovery of neutrino oscillations is one of the most important events in the field of particle physics at the present time. In this work we briefly review the contribution to this achievement of the experiments involving neutrinos emitted by nuclear reactors. First, we show how the reactor flux and its spectrum are determined. Then, we describe the success of the KamLAND experiment that is complementary to the exploration of solar neutrino oscillations, and the determination of the smallest mixing angle θ13 using three independent reactor experiments.

While those achievements involved considerable effort, answering the remaining open questions is even more complicated. We begin by describing the planned large reactor experiments, JUNO and RENO-50, aiming at the difficult determination of the so far unknown neutrino MH or mass ordering. We then touch on the future very short-baseline reactor experiments aiming to test the tentative and unexpected possibility that additional light-sterile neutrinos might exist.

Reactor neutrino flux and spectrum

Nuclear reactors derive their power from fission. The fission fragments are neutron-rich and undergo a cascade of β decays. Each fission is accompanied by approximately six β decays, producing an electron and electron antineutrino each. The decay energy, typical for the nuclear β decay, is a few MeV, rarely exceeding 8 MeV. Since a typical power reactor core has thermal power of about 3 GWth, and produces 200 MeV of energy in each fission, the typical yield of at equilibrium is core−1 s−1. Reactors are therefore powerful sources of low-energy ’s.

Neutrinos can be detected through charged current interactions when they produce charged particles, electron (mass 0.511 MeV), muon (mass 105.7 MeV) or tau (mass 1776.8 MeV), with neutrino energy sufficient to produce them. The reactor energy is low; thus, only reactions producing positrons are possible. Hence, to study neutrino oscillations with nuclear reactors, one must use the disappearance type of tests, that is, measure the flux as a function of the distance L and energy Eν (see Box 1 for the detailed formalism) and look for the deviation from the simple geometrical scaling. Traditionally, such measurements were compared with the expected spectrum of the reactor. Good knowledge of that spectrum, its normalization and the associated uncertainties is essential in that case. To reduce the dependence on the knowledge of the reactor spectrum, more recent experiments20,22 use two essentially similar detectors, one nearer the reactor and another farther away.

There are two principal and complementary ways to evaluate antineutrino spectra associated with fission. The summation method uses known cumulative fission yields Yn(Z, A, t) and combines them with the experimentally known (or theoretically deduced) branching ratios of all β-decay branches with end points and a normalized shape function of each of these many thousands of β decays, ,

There are several difficulties with this method. The branching ratios and end point energies are sometimes poorly known at best, in particular for the short-lived fragments with large Q values and many branches. The individual spectrum shape functions require description of the Coulomb distortions including the nuclear finite size effects, weak magnetism and radiative corrections. In addition, not all decays are of the allowed type. There are numerous (25%) first forbidden decays involving parity change, where the individual spectrum shapes are much more difficult to evaluate.

The other method uses the experimentally determined spectrum of electrons associated with fission of the principal reactor fuels. That spectrum has been measured at ILL Grenoble for the thermal neutron fission of 235U, 239Pu and 242Pu (refs 28, 29, 30) and recently also for the fast neutron fission of 238U in Munich31. These electron spectra are then transformed into the spectra using the obvious fact that these two leptons share the total energy of each β-decay branch. The transformation is on the basis of fitting first the electron spectra to a set of 30 or more virtual branches, with the equidistant end point spacing, determining from the fit their branching ratios. The conversion to the spectrum is performed in each of these virtual branches. That conversion is based on the assumption that the electron spectrum is known precisely. When all virtual branches are put together, one has to also take into account that different nuclear charges Z contribute with different weights to different electron and energies. While the conversion would introduce only minimum uncertainty if all decays would be of the allowed shape, the presence of the first forbidden decays introduces additional uncertainty whose magnitude is difficult to determine accurately.

The summation method was used initially in refs 32, 33, 34, 35, 36 and in the more recent version in ref. 37. The conversion method was first used in refs 28, 29, 30, more details can be found in ref. 38 and the more recent version in ref. 39. Naturally, the thermal power of the reactor and its time-changing fuel composition must be known, as must the energy associated with fissions of the isotopes 235U, 239Pu, 241Pu and 238U. In addition, as already mentioned, small corrections to the spectrum shape of individual β-decay branches due to the radiative correction, weak magnetism, nuclear size, and so on must be correctly included. Difficult to do accurately, but of a particular importance, is to take into account the spectrum shape of the numerous first forbidden β-decays40. The overall uncertainty in the flux was estimated in refs 37, 39 to be 2%; however, when the first forbidden decays are included it is estimated in ref. 40 that the uncertainty increases to 5%.

In essentially all reactor neutrino oscillation studies, the are detected using the inverse neutron β-decay reaction

whose cross-section is accurately known41,42 and depends primarily on the known neutron decay half-life. (At the same time the recoil, radiative corrections and so on must also be taken into account.) Since the neutron is so much heavier than the available energy, its kinetic energy is quite small (tens of keV) and thus the principal observables are the number and energy of the positrons. Most importantly, the correlated observation of the positrons and the delayed neutron captures is a powerful tool for background suppression. Note that the reaction (2) has a threshold of 1.8 MeV, only with energy larger than that can produce positrons.

In Fig. 2 we illustrate the energy dependence of the reactor flux, the detection reaction cross-section and their product, that is, the measured antineutrino spectrum. The contributions of the individual isotopes to the flux, weighted by their typical contribution to the reactor power are also shown. The top part of the figure schematically indicates the steps involved in the capture on proton reaction.

Figure 2: Detection of reactor .
figure 2

In the bottom of the figure, the reactor flux from the individual isotopes37,39, weighted by their typical contribution to the total flux in a commercial reactor, is shown. The detection of relies on the inverse beta decay reaction, whose cross-section41,42 is shown as the blue curve. Their product is the interaction spectrum measured by the detectors, shown as the red curve. The steps involved in the detection are schematically drawn in the top of the figure. The interacts with a proton, becoming a positron (e+) and a neutron. The e+ quickly deposits its energy and annihilates into two 511-keV γ-rays, which gives a prompt signal. The neutron scatters in the detector until being thermalized. It is then captured by a proton 200 μs later and releases a 2.2-MeV γ-ray (the capture time can be significantly reduced by the doping of isotopes with very large neutron capture cross-section such as gadolinium). The detection of this prompt-delayed signal pair indicates an candidate.

Exploring solar neutrino oscillations on earth

Since the late 1960s, a series of solar neutrino experiments43,44,45,46,47, using charged current reactions, have observed a large deficit of the solar νe flux relative to the Standard Solar Model (SSM)48 prediction. It appeared that more than half of the solar neutrinos were missing. This was referred to as the ‘Solar Neutrino Problem’. In 2001, the SNO solar neutrino experiment49, for the first time, successfully measured the total flux of all three neutrino flavours νe, νμ and ντ from the Sun through the neutral current channel ν+dν+p+n using heavy water as a target, that yielded results consistent with the SSM. The SNO result is considered the ‘smoking gun’ evidence of the neutrino oscillation explanation to the Solar Neutrino Problem—the solar neutrinos, produced as electron–neutrinos from fusion and other reactions in the central region of the Sun, are transformed into other flavours when they arrive at the Earth.

The solar neutrino experiments allowed several possible solutions in the oscillation parameter space of θ12 and . A precise measurement of these parameters and demonstration of the oscillatory feature, however, was hindered by the relatively large uncertainty of the solar νe flux predicted by the SSM, the large matter effect inside the Sun and the extremely long distance the neutrinos travel. A reactor neutrino experiment, measuring the same disappearance channel as the solar neutrino experiments assuming CPT invariance, overcomes these difficulties. With well-understood and controllable MeV source, a reactor experiment at 100 km baselines can explore with high precision the so-called ‘Large Mixing Angle’ parameter region suggested by the solar neutrino experiments. To do that, the KamLAND experiment17 was built in early 2000s to explore the solar neutrino oscillations on Earth.

To shield against cosmic rays, the KamLAND detector was placed at the site of the former Kamiokande experiment46 under the summit of Mt. Ikenoyama in the Japanese Alps. The vertical overburden is 2,700 metre water equivalent (m.w.e.). It is surrounded by 55 Japanese nuclear reactor cores, which then produced 30% of the total electricity in Japan. The flux-weighted average baseline is 180 km, well suited for KamLAND to study the parameters suggested by the solar neutrino experiments. The reactor operation information such as thermal power, fuel burn-up and fuel exchange, and enrichment records, were provided by all Japanese reactors, which allowed KamLAND to calculate the instantaneous fission rate of each isotope accurately.

The KamLAND detector consists of 1 kton of highly purified liquid scintillator (LS), enclosed in a 13-m-diameter transparent balloon suspended by ropes in mineral oil (MO). The MO is housed inside a 18-m-diameter stainless steel (SS) sphere, where an array of 1,325 17-inch and 554 20-inch photomultiplier tubes (PMTs) is mounted. The MO shields the inner LS region from external radiation from PMTs and SS. Purified water (3.2 kton) is used to provide further shielding against ambient radiation and it operates as an active cosmic muon veto detector. With regular central-axis deployments of radioactive sources and dedicated off-axis deployments50, KamLAND achieved an excellent position resolution of , energy resolution of and absolute energy-scale uncertainty of 1.4%.

Even with such powerful reactor sources and a massive detector, the long baseline suppresses the expected signal at KamLAND to only about one reactor event per day. In comparison, the background from internal and external radioactivity is one million times higher. The experiment is only possible owing to the powerful coincidence signature (the positron followed by the delayed neutron capture γ) of inverse beta decay, as illustrated in Fig. 2. A time difference of less than 1 ms and distance less than 2 m between the prompt and delayed signals is required in the analysis. Only the innermost 6-m-radius scintillator region is used to reduce the accidental coincidence from external radioactivity. Information about the event energy, position and time was used to further reduce the accidental background to 5% of the candidates.

The other dominant background (10%) at KamLAND is caused by the 13C(α, n)16O reaction where the α-decay comes from 210Po, a decay product of 222Rn that is naturally present in the air and many materials as traces, but is sufficient to induce a measurable contamination of the scintillator during its production. The neutron scattering off proton or 16O* de-excitation produces a prompt signal, followed by a neutron capture-delayed signal. This then mimics a true event. The rest of the backgrounds include the following: the antineutrinos produced in the decay chains of 232Th and 238U in the Earth’s mantle and crust, so-called geoneutrinos; the cosmogenic beta-delayed neutron emitters 9Li and 8He; the fast neutrons from muons passing through the surrounding rock; as well as atmospheric neutrinos.

Figure 3a shows the prompt energy spectrum of candidate events, observed with 2.9 kton·year exposure, overlaid with the expected reactor and background spectra. A total of 1,609 events were observed, which is only 60% of the expected signal if there are no oscillations. The ratio of the background-subtracted candidate events to no-oscillation expectation is plotted in Fig. 3b as a function of L/Eν. The spectrum indicates almost two cycles of the periodic feature expected from neutrino oscillations, strongly disfavouring other explanations of the disappearance.

Figure 3: Results from KamLAND.
figure 3

(a) The data points show the measured prompt energy spectrum of candidate events. The shaded histograms show the expected backgrounds. The expected reactor spectra without oscillation and with best-fit oscillation are shown as the dashed histogram. All histograms incorporate the energy-dependent selection efficiency, which is shown on the top. Only 60% of reactor ’s are observed relative to the no-oscillation expectation. (b) The data points show the ratio of the background-subtracted spectrum to the expectation for no-oscillation as a function of L0/Eν. L0 is the effective baseline taken as a flux-weighted average (L0=180 km). The spectrum indicates almost two cycles of periodic feature as expected from neutrino oscillations. The oscillation survival probability using the best estimates of θ12 and is given by the blue curve. The curve deviates from the perfect sinusoidal L/E dependence since KamLAND has multiple baselines. Panels a,b are reproduced, with permission, from ref. 19. Copyright 2008 by the American Physical Society.

The KamLAND results17,18,19 are highly consistent with the solar neutrino experiments, and have pinned down the solar neutrino oscillation solution to the Large Mixing Angle region. When combined with the results from SNO, they yield the most precise measurements of and . This is a great example of the complementarity between different types of experiments. The SNO and KamLAND’s first results came out within 18 months of each other, with the solar experiment being more sensitive to the mixing angle θ12 and the reactor experiment to the mass-squared difference . The observation of the same effect with two different sources on such different scales provides compelling evidence for neutrino oscillations.

Searching for the smallest oscillation angle

In contrast to the Cabibbo–Kobayashi–Maskawa matrix in quark mixing, where all three mixing angles are very small1, the mixing angles in the neutrino-mixing matrix appear to be large: θ23, measured by the atmospheric51 and long-baseline accelerator52 neutrino experiments, is consistent with 45°, which corresponds to maximal mixing; and θ12, measured by the solar neutrino experiments and KamLAND, is 33°. It was therefore natural to expect that the third mixing angle, θ13, might be of similar magnitude.

The cleanest way to measure θ13 is through kilometre-baseline reactor neutrino oscillation experiments. A non-zero θ13 will cause a deficit of the flux at 1–2 km baseline, as indicated in Fig. 1. The size of the deficit is directly proportional to the value of sin2 2θ13. Unlike accelerator neutrino experiments, the reactor measurements are independent of the CP phase and θ23, and only slightly dependent on the neutrino MH and matter effect. A high precision measurement can therefore be achieved.

In the 1990s, two first-generation kilometre-baseline reactor experiments, CHOOZ53 and PALO VERDE54, were constructed to measure θ13. The CHOOZ detector was built at a distance of 1,050 m from the two reactors of the CHOOZ power plant of Électricité de France in the Ardennes region of France. It took data from April 1997 to July 1998. The PALO VERDE detector was built at distances of 750, 890 and 890 m from the three reactors of the Palo Verde Nuclear Generating Station in the Arizona desert of the United States. It took data between October 1998 and July 2000. Surprisingly, neither experiment was able to observe the deficit caused by θ13 oscillation. As a result, only an upper limit of sin2 2θ13<0.10 at 90% C.L. was obtained53.

The null results from CHOOZ and PALO VERDE, combined with the measured values of θ23 and θ12, motivated many phenomenological speculations of neutrino-mixing patterns such as bimaximal and tribimaximal mixing55,56. In most of these theories, θ13 is either zero or very small. A direct consequence of a vanishing θ13 is that the CP violation in the leptonic sector, even if large, can never be observed in the neutrino oscillation experiments. The importance of knowing the precise value of θ13 provoked a series of worldwide second-generation kilometre-baseline reactor experiments in the twenty-first century, including Double Chooz23 in France, RENO22 in Korea and Daya Bay20 in China, to push the sensitivity to θ13 considerably below 10°. Table 1 summarizes some of the key parameters of the five aforementioned experiments.

Table 1 Key parameters of the reactor θ13 experiments.

A common technology used in both the first- and second-generation experiments is the gadolinium-loaded liquid scintillator as the detection target. Gd has a high thermal neutron capture cross-section. With 0.1% gadolinium loading, the neutron capture time is reduced to 28 from 200 μs for the unloaded scintillator (as used in KamLAND). Furthermore, Gd de-excitation after the neutron capture releases an 8-MeV gamma-ray cascade, which gives a delayed signal well above natural radioactivity (in contrast, neutron capture on a proton releases a single 2.2-MeV γ). The accidental coincidence background is therefore drastically reduced.

Addition of near detectors at baselines of a few hundred metres is the most significant improvement of the second-generation experiments over the previous ones. As discussed above, the uncertainty in predicting the reactor antineutrino flux is relatively large (2–5%). This flux uncertainty, however, can be largely eliminated by the relative measurement between near and far detectors. The Double Chooz experiment expands CHOOZ by adding a near detector at a distance of 400 m. The installation of that near detector, however, was delayed because of civil construction. Double Chooz started taking data in May 2011 with only a far detector, and used the Bugey4 measurement14 to normalize the reactor flux. The RENO experiment was built near the six reactors of the Yonggwang nuclear power plant (NPP) in Korea. The two identical detectors were located at 290 and 1,380 m, respectively, from the centre of the reactor array. RENO started taking data in August 2011. The Daya Bay experiment was built near the six reactors of the Daya Bay NPP in southern China. Daya Bay had eight identical antineutrino detectors (ADs). Two ADs were placed at 360 m from the two Daya Bay reactor cores. Two ADs were placed at 500 m from the four Ling Ao reactor cores. Moreover, four ADs were placed at a far site 1,580 m away from the six-reactor complex. This modular detector design allows Daya Bay to largely remove the correlated detector systematics. Daya Bay started taking data in December 2011.

Compared with the first-generation experiments, the second-generation experiments have much larger signal statistics by utilizing higher power reactors and larger detectors. Among them, Daya Bay has the largest reactor power (17.4 GWth) and target mass (80 tons at the far site), as shown in Table 1. The underground sites are much deeper to allow better shielding from cosmogenic background, in particular compared with the case of PALO VERDE. Better chemical recipes of the gadolinium-loaded liquid scintillator also improve the overall detector performance and long-term stability.

The second-generation reactor experiments were a huge success. In 2012, all three experiments, Double Chooz, Daya Bay and RENO, reported clear evidence of disappearance at kilometre baselines after only a few month’s running20,22,23. In particular, Daya Bay excluded θ13=0 by 5.2 s.d. with 55 days of data20. Figure 4a shows the result of this discovery. The ratio of the detected to expected no-oscillation signals at the six detectors located in the three experimental halls is plotted as a function of weighted baseline. The signal rate at the far site shows an obvious 6% deficit with respect to the near sites, and fits nicely to the theoretical oscillation curve (in red). The precision of the θ13 measurement improved quickly with more data. With the data collected in Daya Bay through November 2013 (ref. 57), the best-fit value is sin2 2θ13=0.084±0.005. Although the last known, the precision in θ13 measurement (6%) is now the best among all three mixing angles.

Figure 4: Results from Daya Bay.
figure 4

(a) The data points show the ratio of the detected to expected no-oscillation signals at the six antineutrino detectors located in three experimental halls (EHs) as a function of the weighted baseline. An 6% signal deficit at the far hall relative to the near halls is observed. The oscillation survival probability at the best-fit value is given by the red curve. The no-oscillation hypothesis (θ13=0) is excluded at 5.2 s.d.’s, as shown in the inset. (b) The data points show the ratio of the background-subtracted spectrum to the expectation for no-oscillation in the three experimental halls as a function of Leff/Eν. The effective baseline Leff is determined for each EH equating the multicore oscillated flux to an effective oscillated flux from a single baseline. A near-complete cycle of the expected periodic oscillation feature is observed. The oscillation survival probability using the best estimates of θ13 and is given by the red curve. Panel a is reproduced, with permission from ref. 20. Copyright 2012 by the American Physical Society. Panel b is reproduced, with permission from ref. 21. Copyright 2014 by the American Physical Society.

Similar to KamLAND, the ratio of the detected events to no-oscillation expectation at Daya Bay is plotted in Fig. 4b as a function of L/Eν. The combined data from the three experimental halls show a near-complete cycle of the expected periodic oscillation feature. The smaller amplitude and shorter wavelength of the oscillation, compared with the case of KamLAND, indicate the different oscillation component driven by θ13 and . The best-fit frequency of the oscillation yields (assuming normal MH), which is consistent and of comparable precision with the measurements of accelerator νμ and disappearance58,59. By the end of 2017, Daya Bay expects to measure both sin2 2θ13 and to precisions below 3% (ref. 57).

The discovery of θ13 represents another good example of the complementarity between different types of experiments. The first results from the reactor experiments20,22,23 and the accelerator experiments60,61 were released within 9 months of each other, with the reactor experiments measuring disappearance and the accelerator experiments measuring νe appearance. Seeing the same θ13-driven effects with different sources of neutrinos at very different energy and baselines is a strong proof of neutrino oscillations.

The longstanding puzzle of the value of θ13 is now successfully resolved. The relatively large value of θ13 opens the gateway for future experiments to determine the neutrino MH and to measure the CP-violating phase in the leptonic sector.

Determination of neutrino MH

At present only the absolute values of the neutrino mass-squared differences and are known, not their sign. Depending on whether both and are positive or whether they are both negative, the neutrino mass ordering is usually referred to as normal or inverted MH, respectively. The neutrino MH is a problem of fundamental importance62 that represents an important step in the formulation of the Generalized Standard Model of particle physics. Its determination will reduce the uncertainty in experiments aiming at the measurement of the CP-violating phase, and it will help in defining the goals of the forthcoming neutrinoless double beta-decay experiments. It will also improve our understanding of core-collapse supernovae.

The reactor oscillations are modulated by terms that depend on and . At a medium baseline of 60 km, multiple small-amplitude, proportional to the sin2 2θ13, oscillation peaks show up on top of the long-wavelength oscillation with the much larger amplitude proportional to the sin2 2θ12, as shown in Fig. 1. Depending on whether the MH is normal or inverted, the small-amplitude oscillation pattern shifts slightly. The MH information can be extracted from this pattern by using a likelihood analysis63 or the Fourier transform method64,65. Additional information regarding the neutrino MH could be obtained by combining the reactor oscillation analysis with the long-baseline muon neutrino disappearance one66, as the effective mass-squared differences measured there are different combinations of , and other oscillation parameters.

Two medium-baseline reactor experiments, JUNO25 in China and RENO-50 (ref. 26) in Korea, have been proposed aiming at the MH determination, among other goals. JUNO is currently under construction. The experiment is located in Kaiping city, Guangdong province, in southern China. The JUNO detector will be placed underground with a total vertical overburden of 1,800 m.w.e. JUNO will observe antineutrinos from the Yangjiang NPP and the Taishan NPP at equal baselines of 53 km, as illustrated in Fig. 5, near the maximal θ12-oscillation baseline. The Yangjiang NPP has six reactor cores of 2.9 GWth each and the Taishan NPP has planned four cores of 4.6 GWth each, both are under construction. The difference between the baselines to the two NPPs is controlled to less than 500 m to prevent significant degradation of the MH discrimination power63. JUNO is expected to start data taking in 2020. The proposed RENO-50 (ref. 26) experiment will be located in the city of Naju, 47 km from the Hanbit NPP with six cores of 2.8 GWth each. The detector will be placed at underground of Mt. Guemseong with an overburden of 900 m.w.e. RENO-50 is expected to begin data taking in 2021.

Figure 5: JUNO’s layout and expected signal.
figure 5

JUNO is located in southern China at an equal baseline of 53 km from the powerful reactors at Yangjiang and Taishan. The shaded histograms in the inset show the expected energy spectra at JUNO with and without backgrounds after 6 years’ running (calculated based on the information given in ref. 25.) The multiple-oscillation structure allows the determination of neutrino mass hierarchy and precision measurement of the oscillation parameters.

The medium-baseline reactor experiments need to have massive detectors, 20 kilotons, in order to collect sufficient events in a reasonable timescale (a few years). In the following we will primarily use JUNO as an example to illustrate the significant challenges in building such a large experiment. The preliminary design of JUNO includes a central detector submerged in a water pool with the muon trackers installed on top of the pool. The water pool is equipped with PMTs and acts as an active Cherenkov detector for vetoing muons. It also provides passive shielding against the natural radioactivities from the surrounding rock and air. The top trackers provide complementary measurements of the cosmic muons. The central detector consists of 20 kton of LS, contained either in a spherical acrylic tank supported by stainless steel frames, or a thin transparent balloon contained in a stainless steel vessel. The detector looks similar to the one in SNO or KamLAND, but is 20 times larger. In order to collect enough light, the central detector is viewed by 18,000 20-inch PMTs. The PMTs have implosion containers to mitigate the risk of implosion chain reactions. Taking into account the mechanical clearance, the PMTs provide a near maximal surface coverage of 75–78%. RENO-50 has a similar detector design with 18-kt LS and 15,000 20-inch PMTs.

An energy resolution better than is essential for medium-baseline reactor experiments to maintain the MH discrimination ability63. To achieve that, besides keeping a maximal photocathode coverage, additional technical improvements are necessary. High quantum-efficiency (35%) PMTs are necessary in order to increase the light-detection efficiency. A new type of 20-inch microchannel plate (MCP) PMTs is being developed for JUNO. The light yield and the optical transparency of the LS also need to be improved. Optimizing the concentration of scintillation fluors, purification of the raw solvent and fluors and online Al2O3 column filtration have been found effective. LS attenuation length of more than 30 m is desired.

Calibration of the absolute energy scale is crucial. In particular, three main effects cause nonlinear energy response of a LS detector: scintillator quenching, Cherenkov radiation and possible nonlinear electronics response. If the energy nonlinearity correction has large uncertainties, particular residual nonlinear shapes may fake the oscillation pattern with a wrong MH67. The absolute energy scale uncertainty needs to be controlled within a few tenths of a percent, which is challenging from the experience of KamLAND50 and Daya Bay57. The requirement demands a comprehensive calibration programme for a large detector such as JUNO or RENO-50.

Background control is demanding, in particular because of relatively shallow depth of the experimental sites of JUNO and RENO-50. The sources of background are similar to those of KamLAND. However, the cosmogenic 9Li and 8He background is significant because of the much higher muon rate. The 9Li and 8He isotopes are mostly produced by the muons accompanied by large electromagnetic or hadronic showers68. In KamLAND, if a shower muon is tagged, the whole detector is vetoed for 2 s. Such a veto strategy will lead to a significant signal loss at JUNO and RENO-50. Since the lateral distance of the isotopes from the parent muon trajectory is approximately exponential68, a small veto region along the muon track can efficiently remove the background with minimal loss of signals. Thus, the ability to track the shower muons is essential, which demands new developments in the muon veto system and improvements on the simulations and reconstructions.

JUNO will observe 60 reactor events per day. The expected energy spectrum is shown in Fig. 5. The sensitivity of the MH determination at JUNO is estimated to exceed 3σ (for the statistical interpretations see refs 69, 70) in 6 years63,71. Assuming that the effective mass-squared difference measured by the ongoing accelerator experiments can achieve 1.5–1% precision72, the MH sensitivity at JUNO can be improved to 3.7–4.4σ (ref. 63). RENO-50 has similar sensitivity reaches. In addition to the MH determination, both JUNO and RENO-50 have great potentials in the precision measurements of the neutrino oscillation parameters. The experiments expect to measure and sin2θ12 to precisions better than 1%. This offers a major step towards the unitarity test of the neutrino mixing matrix73 and is important to guide the directions of future experiments and theories.

The next-generation medium-baseline reactor experiments provide a unique opportunity to determine the neutrino MH with the precision measurement of the reactor neutrino spectrum. Most systematic effects are well understood and studied, although the technical challenges are significant. The MH sensitivity is expected to reach 3–4σ. The reactor measurements are independent of θ23, the CP-violating phase and the matter effect. Combining with the future long-baseline accelerator74,75 and atmospheric76,77 neutrino oscillation programmes, we will once again have complementary measurements of the neutrino MH with different types of experiments. Such complementarity has proved essential in the history of establishing the phenomenon of neutrino oscillations.

Searching for sterile neutrinos

Precision electroweak measurements of the decay width of the Z boson determine the number of active light neutrinos. The result, 2.92±0.05 (ref. 78), is obviously compatible with the three neutrino flavours. The three-neutrino framework has been extremely successful in explaining neutrino oscillation results, since only two oscillation frequencies, corresponding to the two mass-squared differences ( and ), were observed by the solar, atmospheric, accelerator and reactor neutrino oscillation experiments. However, in the 1990s, the LSND experiment79,80 reported an anomalous event excess in the appearance channel, which could be interpreted as an oscillation with the Δm21 eV2. Such a scale is clearly incompatible with the above and . Since the LSND result contradicted the three-neutrino framework, it is often referred to as the ‘LSND anomaly’.

The LSND anomaly indicates the existence of additional fourth or more neutrino families with masses m1 eV. Since these additional neutrinos cannot couple to Z bosons, they must lack weak interactions and are therefore sterile. Sterile neutrinos are observable only through their sub-dominant mixing with the familiar active neutrinos. The light sterile neutrinos, coincidentally, are also among the leading candidates to resolve outstanding puzzles in astrophysics and cosmology81,82,83,84. On the other hand, the light sterile neutrinos are generally not ‘natural’ in the theories that extend the neutrino Standard Model. For example, the popular type-I see-saw model85,86,87,88, which provides an elegant explanation of the small neutrino masses and the matter-antimatter asymmetry of the universe89, predicts only heavy sterile neutrinos (m>1010 eV). If the light sterile neutrinos indeed exist, as LSND indicates, they would suggest new frontiers in both experimental and theoretical physics.

The LSND anomaly so-far remains experimentally unconfirmed, despite many efforts. However, there are several hints supporting LSND’s findings, even though none are really conclusive. The MiniBooNE experiment, designed at a similar L/E baseline as LSND using accelerator neutrinos, observed event excess in the νμνe and appearance channels that have been interpreted as consistent with LSND90,91. The GALLEX92 and the SAGE93 solar neutrino experiments, during their calibrations using intense neutrino sources (51Cr, 37Ar), observed an 24% event deficit in the νe disappearance channel. This deficit is often referred to as the ‘Gallium anomaly’. Recently, re-evaluations of the reactor flux resulted in an increase in the predicted rate37,39 (see earlier sections for details). Combining the new predictions with the reactor experimental data at baselines between 10 and 100 m (refs 9, 10, 11, 12, 13, 14, 15) suggests an 4–6% deficit between the measured and predicted reactor flux, so-called ‘reactor antineutrino anomaly’27,94. These experimental anomalies can be interpreted by light-sterile neutrinos95, but might also be caused by an imperfect knowledge of the theoretical predictions or experimental systematics. The preferred region (Δm21 eV2 and sin2 2θ0.1), however, is in some tension with the limits derived from other appearance96,97,98,99 or disappearance searches15,100,101,102,103,104,105,106,107.

There is, therefore, a strong motivation, despite the rather confusing present experimental status, to search for the light-sterile neutrinos. This led to a high-priority world-wide programme108 with many proposed next-generation neutrino oscillation experiments. Different technologies will be used, including short-baseline accelerator experiments109,110,111,112,113 with various neutrino beams, 51Cr (144Ce–144Pr) νe source experiments114,115,116,117 near or inside large LS detectors, as well as very short-baseline (10 m) reactor (VSBR) experiments. In order to unambiguously resolve the LSND anomaly, the oscillation pattern in the space need to be observed, as in KamLAND (Fig. 3) and Daya Bay (Fig. 4). VSBR experiments provide unique opportunities to do so, given the many advantages provided by reactors.

Multiple VSBR experiments have been proposed globally; in the United States (PROSPECT118, NuLat119), France (NUCIFER120,121, STEREO108), Russia (DANSS122, NEUTRINO-4 (ref. 123, 124), POSEIDON125), United Kingdom (SOLID126) and Korea (HANARO127). Table 2 summarizes some of the key parameters of the proposed VSBR experiments. The oscillation length of the 1-eV mass-scale sterile neutrinos is 10 m for reactor ’s; thus, all proposed experiments deploy their detectors at distances of 4–20 m from the reactor cores. The reactor cores should preferably be compact in size to minimize the oscillations inside the cores; therefore, most experiments utilize compact research reactors with thermal power of tens of megawatts. Those research reactors are typically highly enriched in U, in contrast to the commercial reactors in the NPPs.

Table 2 Key parameters of the very short-baseline reactor experiments.

Background control is a challenging task in the VSBR experiments. The detectors are typically at shallow depth (10 m.w.e.) constrained by the locations of the reactor cores. The cosmic-ray-related background is therefore high. One advantage of using research reactors is that they can be turned on or off on demand, which helps to measure the nonreactor background. The reactor-related backgrounds, such as fast neutrons and high-energy gamma rays, are however more difficult to determine as they appear together with the signals. Sufficient active veto and passive shielding are necessary. However, given the tight space near the reactor cores, they have to be carefully designed.

As shown in Table 2, detectors are typically Gd-loaded or 6Li-loaded liquid (or solid) scintillators. The Gd-LS technology is mature and a good pulse shape discrimination against the neutron background has been demonstrated. An advantage of the 6Li-loaded scintillator is that the delayed neutron capture process 6Li(n, α)t produces an α particle and a triton, instead of a γ-ray. This provides a good localization of the delayed signal and an additional pulse shape discrimination against the γ-background. Some detectors are highly segmented into small cells in order to achieve good position resolution and further background rejection by using the multicell event topologies. There are, however, more inactive layers in the segmented detectors; therefore, the edge effects have to be accurately simulated and measured. It is also more challenging to perform calibrations and control the relative variations among cells for the segmented detectors. For all detectors, sufficient light yield is required to precisely measure the reactor spectrum and the possible distortions from neutrino oscillations.

Despite the challenges, very short-baseline reactor experiments provide a great opportunity to observe the distinctive feature of the light-sterile neutrino oscillations because of their extended range of energy (1–8 MeV) and baselines (5–20 m). The worldwide next-generation VSBR experiments, as shown in Table 2, are being actively considered and pursued. Many of them will begin taking data126 in 2015–2016. Within a few years’ running, they expect to cover the parameter region suggested by the experimental anomalies with a sensitivity better than 5σ and may tell us whether the fascinating possibility of light-sterile neutrinos is true or not.

Outlook

Over the past 60 years, nuclear reactors have proven to be one of the most powerful tools to study neutrino oscillations, the quantum-mechanical phenomenon that requires extensions to the Standard Model. Experiments at a few kilometres and at a few hundred kilometres from the reactor cores have produced some of the most convincing proofs of neutrino oscillations, by observing the oscillatory behaviour of the reactor ’s in the L/E domain during their propagation. Reactor experiments measured several key parameters governing the neutrino mixing, including θ12, θ13, and . They are essential in establishing the framework of neutrino oscillations.

Nuclear reactors will continue to help us uncover more facts about neutrinos. In the next 20 years, the upcoming next-generation reactor experiments will tell us what is the neutrino MH and whether or not light-sterile neutrinos exist. The results will have significant impact on other future programmes such as neutrinoless double-beta decay experiments, long-baseline accelerator experiments, astrophysics and cosmology. Ultimately, they may hold the key to our deeper understanding of fundamental physics and the universe.

Additional information

How to cite this article: Vogel, P. et al. Neutrino oscillation studies with reactors. Nat. Commun. 6:6935 doi: 10.1038/ncomms7935 (2015).