Graf, MatthiasMatthiasGrafNgo, Dinh Bao NamDinh Bao NamNgoWeissmüller, JörgJörgWeissmüllerMarkmann, JürgenJürgenMarkmann2019-02-062019-02-062017-12-19Physical Review Materials 1: (7) 076003 (2017)https://tubdok.tub.tuhh.de/handle/11420/2005X-ray diffraction studies of nanoporous gold face the poorly understood diffraction scenario where large coherent crystals are riddled with nanoscale holes. Theoretical considerations derived in this study show that the ligament size of the porous network influences the scattering despite being quasi single crystalline. Virtual diffraction of artificially generated samples confirms the results but also shows a loss of long-range coherency and the appearance of microstrain due to thermal relaxation. Subsequently, a large set of laboratory X-ray investigations of nanoporous gold fabricated by different approaches and synthesis parameters reveal a clear correlation between ligament size and size of the coherent scattering domains as well as extremely high microstrains in samples with ligament sizes below 10 nm.en2475-995320177076003American Physical Societyhttps://creativecommons.org/licenses/by/4.0/porous crystalsdiffraction pattern simulationPhysikJournal Articleurn:nbn:de:gbv:830-882.02627010.15480/882.200211420/200510.1103/PhysRevMaterials.1.07600310.15480/882.2002Other