The neutrino discovery, by Reines & Cowan, paved the technical ground behind the establishment of much of today’s neutrino detection. Large instrumented volumes can and have been achieved via a key (implicit) principle: detector transparency. Much of that technology has yielded historical success since the 50’s, including several Nobel prizes. The discovery of Neutrino Oscillation phenomenon is a stunning example, solving the long standing “Solar” and “Atmospheric” anomalies by SNO and SuperKamiokande — along with many other experiments. Despite the remarkable success, much of such a “transparent technology” is known to suffer from some key limitations even after 70 years of maturity towards perfection. The challenge continues to be to endow detectors with powerful active background rejection while allowing large volume articulation. Indeed, poor particle identification is a long standing issue, only alleviated by adding external shield (active or passive), which implies a major overburden to the underground laboratories. In this seminar, I shall present for the first time a new technology, under intense R&D, called “LiquidO” relying heavily on detection medium opacity for the first time. The effort is led by the LiquidO proto-collaboration (~20 institutions over ~10 countries). We shall compare LiquidO to its transparent counterpart for maximal appreciation. While not perfect, LiquidO seems to one able to offer several detection features that might lead to breakthrough potential in the context of both neutrino and rare decay physics. This will be briefly highlighted too.
Now @ CNRS-IN2P3 National Staff Scientist (since 2007) affiliated to the "Linear Accelerator Laboratory" (Orsay, France)
•Spokesperson LiquidO Collaboration [with Prof. Suekane (RCNS, Japan)]
•Spokesperson Double Chooz Collaboration
•Coordinator JUNO Dual-Calorimetry System
•CNRS-IN2P3 Responsible for JUNO, Double Chooz and LiquidO R&D Projects
•Director LNCA Underground Laboratory (Chooz, France)
PAST: PhD(Oxford on Neutrino Physics in MINOS).