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The Modular Neutron Array consists of 144 individual detector modules. Each module is based on a plastic [[scintillator]] measuring 10 cm by 10 cm by 200 cm. This scintillator bar is fitted with light guides on each end that direct the light into one [[photo-multiplier tube]] on each end. Each detector module is wrapped in a light-tight material, allowing the detector array to be arranged in different configurations.
In its original configuration, MoNA consisted of 9 vertical layers of 16 detectors stacked closely, having an active area of 2.0 m wide by 1.6 m tall. In its current arrangement (depicted in the adjacent image), it is stacked in four separate sections of 2, 2, 2, and 3 layers each, respectively, separated by spaces ranging from 0.5 to 0.8 meters. It measures both the position and time of neutron events with multiple-hit capability. The energy of a neutron is based on a time-of-flight measurement. This information together with the detected position of the neutron is used to construct the momentum vector of the neutrons.<ref>{{citation| last1= Luther| first1= B.| last2= Baumann| first2= T.| last3= Thoennessen| first3= M.| last4= Brown| first4= J.| last5= DeYoung| first5= P.| last6= Finck| first6= J.| last7= Hinnefeld| first7= J.| last8= Howes| first8= R.| last9= Kemper| first9= K.| last10= Pancella| first10= P.| last11= Peaslee| first11= G.| last12= Rogers| first12= W.| last13= Tabor| first13= S.| date= June 2003| doi= 10.1016/s0168-9002(03)01014-3| issue=
The detection efficiency of MoNA is maximized for the high-beam velocities that are available at the NSCL's Coupled Cyclotron Facility (CCF). For neutrons ranging from 50 to 250 [[MeV]] in energy, it is designed to have an efficiency of up to 70% and expands the possible coincidence experiments with neutrons to measurements which were previously not feasible. The detector is used in combination with the Sweeper magnet<ref>{{citation| last1= Zelevinsky| first1= V.| last2= Volya| first2= A.| editor1-last= Woehr| editor1-first= A.| editor2-last= Aprahamian| editor2-first= A.| contribution= Continuum Shell Model, Reactions and Giant Resonances| doi= 10.1063/1.2187905| pages= 493–497| publisher= American Institute of Physics| series= AIP Conference Proceedings| title= Capture Gamma-Ray Spectroscopy and Related Topics: 12th International Symposium, 4–9 September 2005, Notre Dame, Indiana| volume= 819| year= 2006}}</ref><ref>{{citation| last1= Prestemon| first1= S.| last2= Bird| first2= M. D.| last3= Crook| first3= D. G.| last4= DeKamp| first4= J. C.| last5= Eyssa| first5= Y. M.| last6= Morris| first6= L.| last7= Thoennessen| first7= M.| last8= Zeller| first8= A.| date= March 2001| doi= 10.1109/77.920115| issue= 1| journal= IEEE Transactions on Applied Superconductivity| pages= 1721–1724| title= Structural design and analysis of a compact sweeper magnet for nuclear physics| volume= 11| bibcode= 2001ITAS...11.1721P| display-authors=3}}</ref><ref>{{citation| last1= Toth| first1= J.| last2= Bird| first2= M. D.| last3= Miller| first3= J. R.| last4= Prestemon| first4= S.| last5= DeKamp| first5= J. C.| last6= Morris| first6= L.| last7= Thoennessen| first7= M.| last8= Zeller| first8= A.| date= March 2002| doi= 10.1109/tasc.2002.1018415| issue= 1| journal= IEEE Transactions on Applied Superconductivity| pages= 341–344| title= Final design of a compact sweeper magnet for nuclear physics| volume= 12| bibcode= 2002ITAS...12..341T| display-authors=3}}</ref><ref>{{citation |last1=Bird |first1=M. D. |last2=Bole |first2=S. |last3=Gundlach |first3=S. |last4=Kenney |first4=S. |last5=Miller |first5=J. |last6=Toth |first6=J. |last7=Zeller |first7=A. |date=June 2004 |doi=10.1109/tasc.2004.829720 |issue=2 |journal=IEEE Transactions on Applied Superconductivity |pages=564–567 |title=Cryostat Design and Fabrication for the NHMFL/NSCL Sweeper Magnet |volume=14 |bibcode=2004ITAS...14..564B |s2cid=34670655 |display-authors=3}}</ref><ref>{{citation |last1=Bird |first1=M. D. |last2=Kenney |first2=S. J. |last3=Toth |first3=J. |last4=Weijers |first4=H. W. |last5=DeKamp |first5=J. C. |last6=Thoennessen |first6=M. |last7=Zeller |first7=A. F. |date=June 2005 |doi=10.1109/tasc.2005.849553 |issue=2 |journal=IEEE Transactions on Applied Superconductivity |pages=1252–1254 |title=System Testing and Installation of the NHMFL/NSCL Sweeper Magnet |volume=15 |bibcode=2005ITAS...15.1252B |s2cid=24997693 |display-authors=3}}</ref> and its focal plane detectors for charged particles.<ref>{{citation| first=N.| last=Frank| type=Ph.D. Thesis| title=Spectroscopy of Neutron Unbound States in Neutron Rich Oxygen Isotopes| publisher=Michigan State University| year=2006}}</ref> In addition, MoNA’s modular design allows it to be transported between experimental vaults and thus to be used in combination with the Sweeper magnet installed at the S800 magnet spectrograph.<ref>{{citation |last1=Bazin |first1=D. |last2=Caggiano |first2=J. A. |last3=Sherrill |first3=B. M. |last4=Yurkon |first4=J. |last5=Zeller |first5=A. |date=May 2003 |doi=10.1016/s0168-583x(02)02142-0 |journal=Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms |pages=629–633 |title=The S800 spectrograph |volume=204 |bibcode=2003NIMPB.204..629B |display-authors=3}}</ref> Due to its high-energy detection efficiency, this detector will be well suited for experiments with fast fragmentation beams at the proposed ISF.
== History ==
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