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Acoustic Injectors for Drop-On-Demand Serial Femtosecond Crystallography.Goniometer-based femtosecond crystallography with X-ray free electron lasers.Simultaneous Femtosecond X-ray Spectroscopy and Diffraction of Photosystem II at Room TemperatureRoom temperature femtosecond X-ray diffraction of photosystem II microcrystalsAccurate macromolecular structures using minimal measurements from X-ray free-electron lasersTaking snapshots of photosynthetic water oxidation using femtosecond X-ray diffraction and spectroscopy.Structure of CPV17 polyhedrin determined by the improved analysis of serial femtosecond crystallographic dataImproved crystal orientation and physical properties from single-shot XFEL stills.New Python-based methods for data processing.Data Exploration Toolkit for serial diffraction experiments.A revised partiality model and post-refinement algorithm for X-ray free-electron laser dataMicroED data collection and processing.Stochastic reaction-diffusion simulation with MesoRD.The Mn₄Ca photosynthetic water-oxidation catalyst studied by simultaneous X-ray spectroscopy and crystallography using an X-ray free-electron laser.Methods development for diffraction and spectroscopy studies of metalloenzymes at X-ray free-electron lasers.dxtbx: the diffraction experiment toolbox.Protein crystal structure obtained at 2.9 Å resolution from injecting bacterial cells into an X-ray free-electron laser beamNanoflow electrospinning serial femtosecond crystallographyEnergy-dispersive X-ray emission spectroscopy using an X-ray free-electron laser in a shot-by-shot modeA moment invariant for evaluating the chirality of three-dimensional objects.Indexing amyloid peptide diffraction from serial femtosecond crystallography: new algorithms for sparse patternsEnabling X-ray free electron laser crystallography for challenging biological systems from a limited number of crystals.The collection of MicroED data for macromolecular crystallography.Modeling truncated pixel values of faint reflections in MicroED images.Atomic resolution structure determination by the cryo-EM method MicroED.Flow-aligned, single-shot fiber diffraction using a femtosecond X-ray free-electron laser.Structure of the toxic core of α-synuclein from invisible crystalsAb initio structure determination from prion nanocrystals at atomic resolution by MicroED.L-Edge X-ray Absorption Spectroscopy of Dilute Systems Relevant to Metalloproteins Using an X-ray Free-Electron Laser.Atomic structures of fibrillar segments of hIAPP suggest tightly mated β-sheets are important for cytotoxicity.Structure of catalase determined by MicroEDAtomic-resolution structures from fragmented protein crystals with the cryoEM method MicroED.Towards in cellulo virus crystallography.Erratum: Corrigendum: Accurate macromolecular structures using minimal measurements from X-ray free-electron lasersFree-electron laser data for multiple-particle fluctuation scattering analysisPattern-recognition-based detection of planar objects in three-dimensional electron-density mapsReal-space analysis of radiation-induced specific changes with independent component analysisMicroED data collection with SerialEMAnalysis of Global and Site-Specific Radiation Damage in Cryo-EMThe CryoEM Method MicroED as a Powerful Tool for Small Molecule Structure Determination
P50
Q27303513-64D33CEB-5C22-4AB8-A9BB-16BAF1E43DD4Q27644521-A8ABD874-26AA-410D-81C7-44F9FDD35477Q27676393-6073E24E-298A-4348-A2BB-A54E6AC06F1FQ27679501-F5D3C491-0ED4-402A-829B-C4EB7E39D6DCQ27682246-986D0D31-316F-42CE-80FC-E7089FE85FD4Q27684626-6798F5EC-A01B-4927-A7A8-654EFD7689BFQ28649464-532981CB-D685-449D-B8BA-9E28C50A5ABCQ30422176-1FEBEEEC-3A8C-4901-B8FA-9B9DC22319BFQ30651046-08BB2E77-3F0A-4DAE-BF18-E660798B099FQ30890374-55C275B9-0022-400C-AB51-FA49AEB0865EQ30968461-0E3A14A1-9534-42E2-B8B1-0AA61AF8D88DQ30978045-C34C9DBB-C32D-4588-B091-2B51ED461A73Q31158561-1F7CCEF8-97B9-45C8-A4C4-38747EA12EE8Q33738389-EA4A4B2C-45AB-474A-8C29-E079A4C6C7C0Q33738441-7116B230-8654-4A92-BFF5-BC6B1E35C2DEQ33994191-CA8F72D9-B529-4746-8C1C-0F40D011320CQ34144217-9409F621-1038-4FD9-B956-FF0FD91C42B9Q34454791-F8154987-2857-48CF-B637-770A793386F2Q34468069-B79148CB-8529-4686-BEF5-8C73CCE83EEFQ34509717-DC4D03BC-0B2B-410B-A6BE-8B0872573A53Q35063247-6B8D082B-C897-4D53-89C8-43BA9C874192Q35427600-1435D6B1-7D55-45A4-89AE-ADFA652A30E4Q35989421-FE8D27C4-E646-4040-AA18-5E2820507E5DQ36044605-0BD0ADDA-9EA6-474A-A5F7-52439D4106C6Q36084217-B13BB6B9-7AB9-413C-9B7F-123175BC1C3CQ36390567-F7AAF36C-5854-49AB-AFA8-38D2ED8F016DQ36685232-7DE2E9B5-5731-449C-AA8C-7F8EC278F685Q37323015-D10B9729-CFA4-4D90-BAB3-A764D3EE3A68Q37513169-4EBA8535-5F67-435F-B732-9F63C0D4F273Q37552594-DEB3F006-5F11-42F8-A5E8-60B1922E7F0FQ41607227-EC2AD54E-7D38-4F00-B240-19647BC6E0EEQ42103282-74216C05-3485-4D24-B4D3-F659BDB0B5ACQ52680670-0C830AB0-CD48-403D-B83C-9E18EEEF33AEQ56045976-839F07BA-3C2D-4C08-8AEA-817488A14FA6Q57050127-3A5A7358-8CA5-4595-A27A-226CE9178652Q57215092-BAB3D995-2A57-460A-86D3-1DAA69E077EEQ57993072-87CC1243-BFA2-437F-B373-11FBD3F0870AQ58037983-3F939172-8953-4F5C-8C54-058FEE904804Q58037985-4CCCF494-DB43-4846-AAAB-013E57201B98Q59485557-26F016E8-AD10-4A97-90A4-A9532965F755
P50
description
Zweeds onderzoeker
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հետազոտող
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Hattne J
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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Johan Hattne
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P108
P106
P108
P19
P21
P27
P31
P4012
P496
0000-0002-8936-0912
P569
1976-01-17T00:00:00Z