In-Situ X-Ray Tomographic Study of Materials
This book illustrates the exciting possibilities being opened up by X-ray computed tomography (CT) to follow the behavior of materials under conditions as close as possible to those encountered during their manufacture or in operation.The scientific chapters selected for this book describe results o...
I tiakina i:
| Hōputu: | Online |
|---|---|
| Reo: | Ingarihi |
| I whakaputaina: |
MDPI - Multidisciplinary Digital Publishing Institute
2021
|
| Ngā marau: | |
| Urunga tuihono: | ONIX_20210501_9783039365296_428 |
| Ngā Tūtohu: |
Kāore He Tūtohu, Me noho koe te mea tuatahi ki te tūtohu i tēnei pūkete!
|
| _version_ | 1869526554646675456 |
|---|---|
| collection | Directory of Open Access Books |
| description | This book illustrates the exciting possibilities being opened up by X-ray computed tomography (CT) to follow the behavior of materials under conditions as close as possible to those encountered during their manufacture or in operation.The scientific chapters selected for this book describe results obtained using synchrotron or laboratory devices during in situ or ex situ experiments. They characterize microstructures across length scales ranging from tens of nanometers to a few tens of micrometers.In this collection, X-ray CT shines a light on the mechanical properties of engineering materials, such as aluminum or magnesium alloys, stainless steel, aluminum, polymer composites, or ceramic foam. In these experiments, X-ray CT is able to image and quantify the damage occurring during tensile, compression, indentation, or fatigue tests.Of course, X-ray CT can illuminate the structure and behavior of natural materials too. Here it is applied to bone or natural snow to study their mechanical behavior, as well as materials from the agri-food sector. Its versatility is exemplified by analyses of topics as diverse as the removal of olive oil from kitchen sponges by squeezing and rinsing, to the effect of temperature changes on the structure of ice cream. |
| format | Online |
| id | doab-20.500.12854ir-68682 |
| institution | Directory of Open Access Books |
| language | eng |
| publishDate | 2021 |
| publishDateRange | 2021 |
| publishDateSort | 2021 |
| publisher | MDPI - Multidisciplinary Digital Publishing Institute |
| publisherStr | MDPI - Multidisciplinary Digital Publishing Institute |
| record_format | ojs |
| spelling | doab-20.500.12854ir-686822022-01-31T15:42:58Z In-Situ X-Ray Tomographic Study of Materials Maire, Eric Adrien, Jerome Withers, Philip John in-situ X-ray computed tomography thermal-mechanical loading polymer bonded explosives mesoscale characterization structure evolution particle morphology heat treatment aluminum cast alloy mechanical properties Ostwald ripening nanotomography phase-contrast imaging tomographic reconstruction dynamic tomography motion compensation projection-based digital volume correlation X-ray μCT in-situ experiments flow cell alkaline manganese batteries X-ray tomography in operando in situ zinc powder laser powder bed fusion additive manufacturing in-situ imaging Ti6Al4V lattice structures mechanics corrosion biomaterial battery aluminum foams intermetallics finite element analysis damage polycrystal plasticity X-ray diffraction imaging topotomography in situ experiment finite element simulation lattice curvature rocking curve ice cream microstructure tomography ice crystals coarsening soft solids bone X-ray radiation tissue damage SR-microCT digital volume correlation temperature control electrochemical cell design batteries helical CT contrast agent high cycle fatigue (HCF) fibre break fibre tows Freeze Foaming in situ computed tomography non-destructive testing bioceramics aging crack initiation and propagation damage modes osteoporosis osteogenesis imperfecta porosity bone matrix quality micro-CT snow grains snow microstructure snow properties pore morphology voids fiber-reinforced concrete CT scan technology DIP software X-ray tomography (X-ray CT) 3D image analysis hydrogen embrittlement stainless steel This book illustrates the exciting possibilities being opened up by X-ray computed tomography (CT) to follow the behavior of materials under conditions as close as possible to those encountered during their manufacture or in operation.The scientific chapters selected for this book describe results obtained using synchrotron or laboratory devices during in situ or ex situ experiments. They characterize microstructures across length scales ranging from tens of nanometers to a few tens of micrometers.In this collection, X-ray CT shines a light on the mechanical properties of engineering materials, such as aluminum or magnesium alloys, stainless steel, aluminum, polymer composites, or ceramic foam. In these experiments, X-ray CT is able to image and quantify the damage occurring during tensile, compression, indentation, or fatigue tests.Of course, X-ray CT can illuminate the structure and behavior of natural materials too. Here it is applied to bone or natural snow to study their mechanical behavior, as well as materials from the agri-food sector. Its versatility is exemplified by analyses of topics as diverse as the removal of olive oil from kitchen sponges by squeezing and rinsing, to the effect of temperature changes on the structure of ice cream. 2021-05-01T15:26:45Z 2021-05-01T15:26:45Z 2020 book ONIX_20210501_9783039365296_428 9783039365296 9783039365302 https://directory.doabooks.org/handle/20.500.12854/68682 eng application/octet-stream Attribution 4.0 International https://mdpi.com/books/pdfview/book/2446 https://mdpi.com/books/pdfview/book/2446 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-03936-530-2 10.3390/books978-3-03936-530-2 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783039365296 9783039365302 302 Basel, Switzerland open access |
| spellingShingle | in-situ X-ray computed tomography thermal-mechanical loading polymer bonded explosives mesoscale characterization structure evolution particle morphology heat treatment aluminum cast alloy mechanical properties Ostwald ripening nanotomography phase-contrast imaging tomographic reconstruction dynamic tomography motion compensation projection-based digital volume correlation X-ray μCT in-situ experiments flow cell alkaline manganese batteries X-ray tomography in operando in situ zinc powder laser powder bed fusion additive manufacturing in-situ imaging Ti6Al4V lattice structures mechanics corrosion biomaterial battery aluminum foams intermetallics finite element analysis damage polycrystal plasticity X-ray diffraction imaging topotomography in situ experiment finite element simulation lattice curvature rocking curve ice cream microstructure tomography ice crystals coarsening soft solids bone X-ray radiation tissue damage SR-microCT digital volume correlation temperature control electrochemical cell design batteries helical CT contrast agent high cycle fatigue (HCF) fibre break fibre tows Freeze Foaming in situ computed tomography non-destructive testing bioceramics aging crack initiation and propagation damage modes osteoporosis osteogenesis imperfecta porosity bone matrix quality micro-CT snow grains snow microstructure snow properties pore morphology voids fiber-reinforced concrete CT scan technology DIP software X-ray tomography (X-ray CT) 3D image analysis hydrogen embrittlement stainless steel In-Situ X-Ray Tomographic Study of Materials |
| title | In-Situ X-Ray Tomographic Study of Materials |
| title_full | In-Situ X-Ray Tomographic Study of Materials |
| title_fullStr | In-Situ X-Ray Tomographic Study of Materials |
| title_full_unstemmed | In-Situ X-Ray Tomographic Study of Materials |
| title_short | In-Situ X-Ray Tomographic Study of Materials |
| title_sort | in situ x ray tomographic study of materials |
| topic | in-situ X-ray computed tomography thermal-mechanical loading polymer bonded explosives mesoscale characterization structure evolution particle morphology heat treatment aluminum cast alloy mechanical properties Ostwald ripening nanotomography phase-contrast imaging tomographic reconstruction dynamic tomography motion compensation projection-based digital volume correlation X-ray μCT in-situ experiments flow cell alkaline manganese batteries X-ray tomography in operando in situ zinc powder laser powder bed fusion additive manufacturing in-situ imaging Ti6Al4V lattice structures mechanics corrosion biomaterial battery aluminum foams intermetallics finite element analysis damage polycrystal plasticity X-ray diffraction imaging topotomography in situ experiment finite element simulation lattice curvature rocking curve ice cream microstructure tomography ice crystals coarsening soft solids bone X-ray radiation tissue damage SR-microCT digital volume correlation temperature control electrochemical cell design batteries helical CT contrast agent high cycle fatigue (HCF) fibre break fibre tows Freeze Foaming in situ computed tomography non-destructive testing bioceramics aging crack initiation and propagation damage modes osteoporosis osteogenesis imperfecta porosity bone matrix quality micro-CT snow grains snow microstructure snow properties pore morphology voids fiber-reinforced concrete CT scan technology DIP software X-ray tomography (X-ray CT) 3D image analysis hydrogen embrittlement stainless steel |
| topic_facet | in-situ X-ray computed tomography thermal-mechanical loading polymer bonded explosives mesoscale characterization structure evolution particle morphology heat treatment aluminum cast alloy mechanical properties Ostwald ripening nanotomography phase-contrast imaging tomographic reconstruction dynamic tomography motion compensation projection-based digital volume correlation X-ray μCT in-situ experiments flow cell alkaline manganese batteries X-ray tomography in operando in situ zinc powder laser powder bed fusion additive manufacturing in-situ imaging Ti6Al4V lattice structures mechanics corrosion biomaterial battery aluminum foams intermetallics finite element analysis damage polycrystal plasticity X-ray diffraction imaging topotomography in situ experiment finite element simulation lattice curvature rocking curve ice cream microstructure tomography ice crystals coarsening soft solids bone X-ray radiation tissue damage SR-microCT digital volume correlation temperature control electrochemical cell design batteries helical CT contrast agent high cycle fatigue (HCF) fibre break fibre tows Freeze Foaming in situ computed tomography non-destructive testing bioceramics aging crack initiation and propagation damage modes osteoporosis osteogenesis imperfecta porosity bone matrix quality micro-CT snow grains snow microstructure snow properties pore morphology voids fiber-reinforced concrete CT scan technology DIP software X-ray tomography (X-ray CT) 3D image analysis hydrogen embrittlement stainless steel |
| url | ONIX_20210501_9783039365296_428 |