Nuclear emulsion scanning for double strangeness nuclei search Junya Yoshida, Kazuma Nakazawa, Khin Than Tint, Myint Kyaw Soe, Aye Moh Moh Theint, Shinji Kinbara, Akihiro Mishina, Yoko Endo, Hiroki Ito, Hidetaka Kobayashi Physics department, Gifu University, Japan JSPS KAKENHI 23224006 and MEXT 15001001, 24105002 1 Ξ- Double lambda hypernucleus X-ray n n p pn * Important subject to investigate hyperonhyperon interaction. Vertex A np n #1 Λ np np * Tiny characteristic shape having 3 vertexes at the rest point of X- hyperon in nuclear emulsion. n p pΛn p + Ξ- → Λ + Λ + 28MeV Vertex B p Λ π- n p pn Vertex C n p n p n PHYSICAL REVIEW C 88, 014003 (2013) 2 Nuclear emulsion plate: photographic tracking device for charged particles charged particles nuclear emulsion plate layer structure emulsion base emulsion ~450 micron 40 micron ~450 micron AgBr crystals suspended in gelatin. track after photographic development Read-out: by optical microscope 3 Emulsion pictures 4 Only 9 events are observed in 2000s in the world. Various double lambda hypernuclei must be detected to investigate L-L interaction. How we obtain more double lambda hypernuclear events? * The experiment ten times larger than the previous experiment. J-PARC E07 -> Ekawa-san’s talk * PID for daughter nucleus -> Kinbara’s talk Emulsion stack K+ (p>1.0GeV/c) Diamond target KXDouble Lambda Hypernucleus 5 A schematic view of “Track following” thin type plate, good angular resolution: Interface between tracker and emulsion stack. thick type plate, large angular acceptance For detection of nuclear events. PoC. of automated tracking system is ongoing disassembled emulsion stack Only 9 events are observed in 2000s in the world. Various double lambda hypernuclei must be detected to investigate L-L interaction. How we obtain more double lambda hypernuclear events? * The experiment ten times larger than the previous experiment. (J-PARC E07) * PID for daughter nucleus -> Kinbara’s talk * New searching method: Overall-scanning method Diamond target Emulsion stack K- K+ (p>1.0GeV/c) yield: ~30% XKX- K0 Double Lambda Hypernucleus (K-, K0) * Latent events (~10 times) may be recorded in existing emulsion. 7 Overall scanning Concept and Key technologies; (1). 3-dimensional scanning under optical microscopic view. (2). Image process to find multi-vertex shape in emulsion. * High speed is required * The method is also useful to find calibration sources such as, alpha decays, single lambda hypernuclei. * This method will be applied to E07 after regular analysis with hybrid method. 8 (2). Image process J.Yoshida et al., JPS Conf. Proc. , (2014) 1.013070 Original image Difference of Gaussian Binalization Gaussian filter x20 Objective (NA0.35) 1 pix = ~0.6 micron Filter for bold tracks contour length > 5pix area > 10pix kernel size = 17pix (smoothed – source) if negative, brightness=0 Thinning Prob. Hough Trans. resolution = 1degree threshold = 16 pix / line threshold ~= peak*0.2 Vertexing dist-edge-to-edge = 15pix N_Tracks > 3 9 polygon area > 1000pix A. raw image B. blurred brightness(x,y) = B - A brightness(x) brightness(x) = Blurred - Raw Raw Blurred x x if negative, brightness = 0 10 (2). Image process J.Yoshida et al., JPS Conf. Proc. , (2014) 1.013070 Original image Difference of Gaussian Binalization dist-edge-to-edge = 8micron Gaussian filterN_Tracks > 3 polygon area > 300micron2 x20 Objective (NA0.35) 1 pix = ~0.6 micron Filter for bold tracks contour length > 5pix area > 10pix kernel size = 17pix tuned Thinning (smoothed – source) ~= peak*0.2 by Nagara event and somethreshold alpha decays if negative, brightness=0 Prob. Hough Trans. resolution = 1degree threshold = 16 pix / line Vertexing 11 ・extracted images of vertex-like-object 12 Eye check for extracted vertexes example :E373 mod86 pl7 scanned volume: 2.2mm * 10mm * 0.9mm detected candidates: vertex: 361 3496 Alpha decay: 32 Beam Interaction: SingleHyper: 329 6 misrecognition : 3135 Beam Int. Alpha decay crossing‐over of 2tracks: <Ideas for improvement> * Parameter tuning. * Recognition under a higher magnificent optics after 1st level selection. * And so on. 13 (1). A dedicated scanning system(Stage#7,8) camera collaborate with UNIOPT Co. high resolution CMOS 2048*358 pixel high frame rate 800fps objective lens Piezoelectric drive wide F.O.V. x20 dry lens (NA0.35) 1142*200 micron2 Piezoelectric drive stroke 500 micron period 5Hz picture 40picts /cycle emulsion plate Continuously stage moving Designed speed: 10mm*10mm*0.9mm / 2min. = ~40 hours @plate (340*335*0.9[mm3]) To accomplish scanning of ~1000 films within a few year. 14 stage motion in X-Y plane (top view) 2 1 1.0 mm / sec 3 4 Yaxis 1.0 mm / sec Xaxis stage motion in Y-Z plane (cross sectional view) 40 picts. Zaxis Field Of View : 0.2*1.1 [mm2] 200msec /cycle Yaxis 1.0 mm / sec * Exhaustively scanning by a computer-controlled optical microscope. * Continuous stage drive to save damping time of vibration. 15 J.Yoshida et al., JPS Conf. Proc. , (2014) * These are processed in real-time by CPU&GPU (5msec/pict.) (2). Image process 1.013070 * Data is stored in HDDs Difference of Gaussian Original image Binalization Gaussian filter x20 Objective (NA0.35) 1 pix = ~0.6 micron Filter for bold tracks contour length > 5pix area > 10pix kernel size = 17pix (smoothed – source) if negative, brightness=0 Thinning Prob. Hough Trans. resolution = 1degree threshold = 16 pix / line threshold ~= peak*0.2 Vertexing dist-edge-to-edge = 15pix N_Tracks > 3 16 polygon area > 1000pix Quality checking for scanned data Exhaustiveness of image taking Trigger timing Z trigger 50views -> trigger trigger Time or Y Tiled binalized images. 200micron*1140micron*3views The same layer ID number_of_’1’_pixel 40pictures surface base pict.ID 1 10 20 30 40 * Stage drive, piezoelectric, camera are synchronized. Trigger timing is proper. * Missed trigger and troubles in data transfer < 3% 17 Operation Prototype Upgraded High-speed Since ~2011 2014 Stage Camera 100fps CCD Z-drive Stepping motor Optics Field of View 0.11*0.13mm2 0.18*0.21mm2 2013 Speed[mm3/h] 2.6 2700 Site Gifu-univ. Gifu-univ. Toho-univ,Japan GNU,Korea GNU,Korea Scanned vol. ~5.0cc 13.1 just started Found events; ~3000 alpha decays ~700 single hypernuclear event 7 three-vertexes candidates. A typical twin-single-lambda- hypernuclear event (Kiso) 800fps CMOS Piezoelectric 0.20*1.14mm2 Gifu-univ. 17.4cc 10 mm 18 summary * Overall scanning A new searching method for double lambda hypernucleus in emulsion. Concept: high speed 3D scanning & image recognition * The current status Scanning software, Image process is basically successful. Improvement of detection efficiency and S/N ratio is being carried out. *Operation In operation in Gifu-univ., Toho-univ., Japan, GNU, Korea. ~700 candidates of single hypernuclear ~7 3-vertexes candidates. A typical twin-single-lambda- hypernuclear event (Kiso) 19 20 JPS Conf. Proc. , (2014) 1.013070 Image process Difference of Gaussian Raw image Binalization Gaussian filter x20 Objective (NA0.35) 1 pix = ~0.6 micron Filter for bold tracks contour length > 5pix area > 10pix kernel size = 17pix Thinning threshold ~= peak*0.2 (smoothed – source) if negative, brightness=0 Prob. Hough Trans. Vertexing resolution = 1degree dist-edge-to-edge = 15pix threshold = 16 pix / line N_Tracks > 3 polygon area > 1000pix Synclonization between piezoelectricity and camera 400us 3.5V (LVTTL) Host PC CMOS Camera CameraLink Base & Full Piezo Ctrl. TRG 400us 5.0V GPGPU Main Board BNC PCI & PCI-E Grabber Board PiezoElec. USB Stage Ctrl. command USB optics TRG: start sequential shooting Z Emulsion thickness vibration of focal plane driven by Piezoelectricity Time or StageYaxis 22 Stage control Z-Axis (Optics) Host PC Motor Driver (3-axes) X,Y-Axis (Stage) Stage Ctrl. Main Board GPGPU PCI & PCI-E Grabber Board LED Driver command LED Light Serial 23 Data transmission Host PC CMOS Camera RAM Grabber Board PCI & PCI-E GPGPU (GTX680) CPU Corei7 3960X External HDD Chipset Stage Ctrl. (1) (2) (3) (4) (5) (6) (7) X79 eSATA (100MB/s) シリアル Camera -> grabber_board -> RAM RAM -> GPGPU Difference_of_Gaussians on GPGPU GPGPU -> RAM Binalization on CPU RAM -> External HDD Image process on another computer 2048*358 pix 8bit-depth 2048*358 pix 1bit-depth 24 Overall scanning ほかにも、乾板中にランダムに存在するキャリブレーションソース アルファ崩壊、シングルハイパーも探索したい。 そこで ・原子核乾板の全体積を光学顕微鏡で走査し、 (1)高速顕微鏡画像取得の開発 ・少なくとも1つの分岐点をもつパターンを検出 (2) 画像解析の開発 Stage size: 35cm*35cm (Nikon. ) 45cm*45cm (Uniopt. ) Field of View: 115micron*135micron(x50 objective lens) 25 Overall Scanning と解析のストラテジー Phase I : 技術開発 兼 E373乾板の再解析 先の実験(KEK E373)の乾板を用いて技術開発 E373乾板の全体積をスキャンし、 従来比10倍、70例のダブルΛハイパー核検出をねらう Phase II : E07実験解析のアシスト キャリブレーションソース:アルファ崩壊の探索高速化 Phase III : E07乾板の再解析 E07乾板の全体積をスキャンし、 プロポーザル比10倍、103例のダブルΛハイパー核検出をねらう 26
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