Your search keyword '"Nakamura, Atsutomo"' showing total 25 results

1. Switching the fracture toughness of single-crystal ZnS using light irradiation

Author

Zhu, Tingting, Ding, Kuan, Oshima, Yu, Amiri, Anahid, Bruder, Enrico, Stark, Robert W., Durst, Karsten, Matsunaga, Katsuyuki, Nakamura, Atsutomo, Fang, Xufei, Zhu, Tingting, Ding, Kuan, Oshima, Yu, Amiri, Anahid, Bruder, Enrico, Stark, Robert W., Durst, Karsten, Matsunaga, Katsuyuki, Nakamura, Atsutomo, and Fang, Xufei

Abstract

An enormous change in the dislocation-mediated plasticity has been found in a bulk semiconductor that exhibits the photoplastic effect. Herein, we report that UV (365 nm) light irradiation during mechanical testing dramatically decreases the fracture toughness of ZnS. The crack tip toughness on a (001) single-crystal ZnS, as measured by the near-tip crack opening displacement method, is increased by ∼45% in complete darkness compared to that in UV light. The increase in fracture toughness is attributed to a significant increase in the dislocation mobility in darkness, as explained by the crack tip dislocation shielding model. Our finding suggests a route toward controlling the fracture toughness of photoplastic semiconductors by tuning the light irradiation.

Published

2024

2. Switching the fracture toughness of single-crystal ZnS using light irradiation

Author

Zhu, Tingting, Ding, Kuan, Oshima, Yu, Amiri, Anahid, Bruder, Enrico, Stark, Robert W., Durst, Karsten, Matsunaga, Katsuyuki, Nakamura, Atsutomo, Fang, Xufei, Zhu, Tingting, Ding, Kuan, Oshima, Yu, Amiri, Anahid, Bruder, Enrico, Stark, Robert W., Durst, Karsten, Matsunaga, Katsuyuki, Nakamura, Atsutomo, and Fang, Xufei

Abstract

An enormous change in the dislocation-mediated plasticity has been found in a bulk semiconductor that exhibits the photoplastic effect. Herein, we report that UV (365 nm) light irradiation during mechanical testing dramatically decreases the fracture toughness of ZnS. The crack tip toughness on a (001) single-crystal ZnS, as measured by the near-tip crack opening displacement method, is increased by ∼45% in complete darkness compared to that in UV light. The increase in fracture toughness is attributed to a significant increase in the dislocation mobility in darkness, as explained by the crack tip dislocation shielding model. Our finding suggests a route toward controlling the fracture toughness of photoplastic semiconductors by tuning the light irradiation.

Published

2024

3. Influence of dislocations on thermal conductivity of strontium titanate

Author

Johanning, Melanie, Porz, Lukas, Dong, Jinfeng, Nakamura, Atsutomo, Li, Jing-Feng, Rödel, Jürgen, Johanning, Melanie, Porz, Lukas, Dong, Jinfeng, Nakamura, Atsutomo, Li, Jing-Feng, and Rödel, Jürgen

Abstract

Recently, several creative processing techniques yielded thermoelectrics with reduced thermal conductivity and, thereby, an enhanced figure or merit. These were based on engineered complex microstructures with attendant dislocation structures. In this study, we implement highly controlled mesoscopic dislocation structures into the model thermoelectric SrTiO₃ in order to quantify phonon scattering at dislocations. Both single crystals and polycrystalline material have been furnished with enhanced dislocation densities increased by a factor of 150–300 by plastic deformation. Thermal conductivity was measured using laser flash analysis between room temperature and 325 °C. Etch pit techniques and ultra-high voltage electron microscopy afford quantification of dislocation density. Experimental results were compared to predictions by the Debye-Callaway model. The latter revealed that dislocation densities of 10¹⁵ m⁻² would be necessary for the reduction of thermal conductivity of SrTiO₃ in the investigated temperature range, which could not be realized using the plastic deformation mechanism applied.

Published

2023

4. Enhanced Photoconductivity at Dislocations in SrTiO₃

Author

Kissel, Maximilian, Porz, Lukas, Frömling, Till, Nakamura, Atsutomo, Rödel, Jürgen, Alexe, Marin, Kissel, Maximilian, Porz, Lukas, Frömling, Till, Nakamura, Atsutomo, Rödel, Jürgen, and Alexe, Marin

Abstract

Dislocations are 1D crystallographic line defects and are usually seen as detrimental to the functional properties of classic semiconductors. It is shown here that this not necessarily accounts for oxide semiconductors in which dislocations are capable of boosting the photoconductivity. Strontium titanate single crystals are controllably deformed to generate a high density of ordered dislocations of two slip systems possessing different mesoscopic arrangements. For both slip systems, nanoscale conductive atomic force microscope investigations reveal a strong enhancement of the photoconductivity around the dislocation cores. Macroscopic in-plane measurements indicate that the two dislocation systems result in different global photoconductivity behavior despite the similar local enhancement. Depending on the arrangement, the global photoresponse can be increased by orders of magnitude. Additionally, indications for a bulk photovoltaic effect enabled by dislocation-surrounding strain fields are observed for the first time. This proves that dislocations in oxide semiconductors can be of large interest for tailoring photoelectric functionalities. Direct evidence that electronic transport is confined to the dislocation core points to a new emerging research field.

Published

2023

5. Dislocation-toughened ceramics

Author

Porz, Lukas, Klomp, Arne Jan, Fang, Xufei, Li, Ning, Yildirim, Can, Detlefs, Carsten, Bruder, Enrico, Höfling, Marion, Rheinheimer, Wolfgang, Patterson, Eric A., Gao, Peng, Durst, Karsten, Nakamura, Atsutomo, Albe, Karsten, Simons, Hugh, Rödel, Jürgen, Porz, Lukas, Klomp, Arne Jan, Fang, Xufei, Li, Ning, Yildirim, Can, Detlefs, Carsten, Bruder, Enrico, Höfling, Marion, Rheinheimer, Wolfgang, Patterson, Eric A., Gao, Peng, Durst, Karsten, Nakamura, Atsutomo, Albe, Karsten, Simons, Hugh, and Rödel, Jürgen

Abstract

Functional and structural ceramics have become irreplaceable in countless high-tech applications. However, their inherent brittleness tremendously limits the application range and, despite extensive research efforts, particularly short cracks are hard to combat. While local plasticity carried by mobile dislocations allows desirable toughness in metals, high bond strength is widely believed to hinder dislocation-based toughening of ceramics. Here, we demonstrate the possibility to induce and engineer a dislocation microstructure in ceramics that improves the crack tip toughness even though such toughening does not occur naturally after conventional processing. With modern microscopy and simulation techniques, we reveal key ingredients for successful engineering of dislocation-based toughness at ambient temperature. For many ceramics a dislocation-based plastic zone is not impossible due to some intrinsic property (e.g. bond strength) but limited by an engineerable quantity, i.e. the dislocation density. The impact of dislocation density is demonstrated in a surface near region and suggested to be transferrable to bulk ceramics. Unexpected potential in improving mechanical performance of ceramics could be realized with novel synthesis strategies.

Published

2023

6. Dislocation-based high-temperature plasticity of polycrystalline perovskite SrTiO3

Author

Porz, Lukas, Scherer, Michael, Höfling, Marion, Nakamura, Atsutomo, Rheinheimer, Wolfgang, Rödel, Jürgen, Porz, Lukas, Scherer, Michael, Höfling, Marion, Nakamura, Atsutomo, Rheinheimer, Wolfgang, and Rödel, Jürgen

Abstract

Dislocation networks have been demonstrated to substantially enhance functional properties. As-sintered samples are virtually devoid of dislocations, new innovative techniques for introducing sufficiently high dislocation densities into polycrystalline ceramics are needed. While dislocation-based plasticity at high temperatures has been demonstrated for a large range of ceramic single crystals, plasticity in polycrystals is much less understood. Here, we demonstrate plastic strains in excess of several % based on dislocation motion in polycrystalline SrTiO3 at ≈ 1100 °C with 3.9 µm grain size. Ultra-high voltage electron microscopy reveals an associated increase in dislocation density by three orders of magnitude. Achievable strain rates are comparable to creep-based mechanisms and much less sensitive to applied stress than observed for metals. A specialized testing protocol allows quantification of the deformability via stress exponent, activation volume and activation enthalpy giving additional quantification. In conjunction with TEM images, the mechanical data gives insight into the underlying mechanisms.

Published

2023

7. Enhanced Photoconductivity at Dislocations in SrTiO₃

Author

Kissel, Maximilian, Porz, Lukas, Frömling, Till, Nakamura, Atsutomo, Rödel, Jürgen, Alexe, Marin, Kissel, Maximilian, Porz, Lukas, Frömling, Till, Nakamura, Atsutomo, Rödel, Jürgen, and Alexe, Marin

Abstract

Dislocations are 1D crystallographic line defects and are usually seen as detrimental to the functional properties of classic semiconductors. It is shown here that this not necessarily accounts for oxide semiconductors in which dislocations are capable of boosting the photoconductivity. Strontium titanate single crystals are controllably deformed to generate a high density of ordered dislocations of two slip systems possessing different mesoscopic arrangements. For both slip systems, nanoscale conductive atomic force microscope investigations reveal a strong enhancement of the photoconductivity around the dislocation cores. Macroscopic in-plane measurements indicate that the two dislocation systems result in different global photoconductivity behavior despite the similar local enhancement. Depending on the arrangement, the global photoresponse can be increased by orders of magnitude. Additionally, indications for a bulk photovoltaic effect enabled by dislocation-surrounding strain fields are observed for the first time. This proves that dislocations in oxide semiconductors can be of large interest for tailoring photoelectric functionalities. Direct evidence that electronic transport is confined to the dislocation core points to a new emerging research field.

Published

2023

8. Dislocation-toughened ceramics

Author

Porz, Lukas, Klomp, Arne Jan, Fang, Xufei, Li, Ning, Yildirim, Can, Detlefs, Carsten, Bruder, Enrico, Höfling, Marion, Rheinheimer, Wolfgang, Patterson, Eric A., Gao, Peng, Durst, Karsten, Nakamura, Atsutomo, Albe, Karsten, Simons, Hugh, Rödel, Jürgen, Porz, Lukas, Klomp, Arne Jan, Fang, Xufei, Li, Ning, Yildirim, Can, Detlefs, Carsten, Bruder, Enrico, Höfling, Marion, Rheinheimer, Wolfgang, Patterson, Eric A., Gao, Peng, Durst, Karsten, Nakamura, Atsutomo, Albe, Karsten, Simons, Hugh, and Rödel, Jürgen

Abstract

Functional and structural ceramics have become irreplaceable in countless high-tech applications. However, their inherent brittleness tremendously limits the application range and, despite extensive research efforts, particularly short cracks are hard to combat. While local plasticity carried by mobile dislocations allows desirable toughness in metals, high bond strength is widely believed to hinder dislocation-based toughening of ceramics. Here, we demonstrate the possibility to induce and engineer a dislocation microstructure in ceramics that improves the crack tip toughness even though such toughening does not occur naturally after conventional processing. With modern microscopy and simulation techniques, we reveal key ingredients for successful engineering of dislocation-based toughness at ambient temperature. For many ceramics a dislocation-based plastic zone is not impossible due to some intrinsic property (e.g. bond strength) but limited by an engineerable quantity, i.e. the dislocation density. The impact of dislocation density is demonstrated in a surface near region and suggested to be transferrable to bulk ceramics. Unexpected potential in improving mechanical performance of ceramics could be realized with novel synthesis strategies.

Published

2023

9. Influence of dislocations on thermal conductivity of strontium titanate

Author

Johanning, Melanie, Porz, Lukas, Dong, Jinfeng, Nakamura, Atsutomo, Li, Jing-Feng, Rödel, Jürgen, Johanning, Melanie, Porz, Lukas, Dong, Jinfeng, Nakamura, Atsutomo, Li, Jing-Feng, and Rödel, Jürgen

Abstract

Recently, several creative processing techniques yielded thermoelectrics with reduced thermal conductivity and, thereby, an enhanced figure or merit. These were based on engineered complex microstructures with attendant dislocation structures. In this study, we implement highly controlled mesoscopic dislocation structures into the model thermoelectric SrTiO₃ in order to quantify phonon scattering at dislocations. Both single crystals and polycrystalline material have been furnished with enhanced dislocation densities increased by a factor of 150–300 by plastic deformation. Thermal conductivity was measured using laser flash analysis between room temperature and 325 °C. Etch pit techniques and ultra-high voltage electron microscopy afford quantification of dislocation density. Experimental results were compared to predictions by the Debye-Callaway model. The latter revealed that dislocation densities of 10¹⁵ m⁻² would be necessary for the reduction of thermal conductivity of SrTiO₃ in the investigated temperature range, which could not be realized using the plastic deformation mechanism applied.

Published

2023

10. Dislocation-toughened ceramics

Author

Porz, Lukas, Klomp, Arne Jan, Fang, Xufei, Li, Ning, Yildirim, Can, Detlefs, Carsten, Bruder, Enrico, Höfling, Marion, Rheinheimer, Wolfgang, Patterson, Eric A., Gao, Peng, Durst, Karsten, Nakamura, Atsutomo, Albe, Karsten, Simons, Hugh, Rödel, Jürgen, Porz, Lukas, Klomp, Arne Jan, Fang, Xufei, Li, Ning, Yildirim, Can, Detlefs, Carsten, Bruder, Enrico, Höfling, Marion, Rheinheimer, Wolfgang, Patterson, Eric A., Gao, Peng, Durst, Karsten, Nakamura, Atsutomo, Albe, Karsten, Simons, Hugh, and Rödel, Jürgen

Abstract

Functional and structural ceramics have become irreplaceable in countless high-tech applications. However, their inherent brittleness tremendously limits the application range and, despite extensive research efforts, particularly short cracks are hard to combat. While local plasticity carried by mobile dislocations allows desirable toughness in metals, high bond strength is widely believed to hinder dislocation-based toughening of ceramics. Here, we demonstrate the possibility to induce and engineer a dislocation microstructure in ceramics that improves the crack tip toughness even though such toughening does not occur naturally after conventional processing. With modern microscopy and simulation techniques, we reveal key ingredients for successful engineering of dislocation-based toughness at ambient temperature. For many ceramics a dislocation-based plastic zone is not impossible due to some intrinsic property (e.g. bond strength) but limited by an engineerable quantity, i.e. the dislocation density. The impact of dislocation density is demonstrated in a surface near region and suggested to be transferrable to bulk ceramics. Unexpected potential in improving mechanical performance of ceramics could be realized with novel synthesis strategies.

Published

2023

11. Influence of dislocations on thermal conductivity of strontium titanate

Author

Johanning, Melanie, Porz, Lukas, Dong, Jinfeng, Nakamura, Atsutomo, Li, Jing-Feng, Rödel, Jürgen, Johanning, Melanie, Porz, Lukas, Dong, Jinfeng, Nakamura, Atsutomo, Li, Jing-Feng, and Rödel, Jürgen

Abstract

Recently, several creative processing techniques yielded thermoelectrics with reduced thermal conductivity and, thereby, an enhanced figure or merit. These were based on engineered complex microstructures with attendant dislocation structures. In this study, we implement highly controlled mesoscopic dislocation structures into the model thermoelectric SrTiO₃ in order to quantify phonon scattering at dislocations. Both single crystals and polycrystalline material have been furnished with enhanced dislocation densities increased by a factor of 150–300 by plastic deformation. Thermal conductivity was measured using laser flash analysis between room temperature and 325 °C. Etch pit techniques and ultra-high voltage electron microscopy afford quantification of dislocation density. Experimental results were compared to predictions by the Debye-Callaway model. The latter revealed that dislocation densities of 10¹⁵ m⁻² would be necessary for the reduction of thermal conductivity of SrTiO₃ in the investigated temperature range, which could not be realized using the plastic deformation mechanism applied.

Published

2023

12. Enhanced Photoconductivity at Dislocations in SrTiO₃

Author

Kissel, Maximilian, Porz, Lukas, Frömling, Till, Nakamura, Atsutomo, Rödel, Jürgen, Alexe, Marin, Kissel, Maximilian, Porz, Lukas, Frömling, Till, Nakamura, Atsutomo, Rödel, Jürgen, and Alexe, Marin

Abstract

Dislocations are 1D crystallographic line defects and are usually seen as detrimental to the functional properties of classic semiconductors. It is shown here that this not necessarily accounts for oxide semiconductors in which dislocations are capable of boosting the photoconductivity. Strontium titanate single crystals are controllably deformed to generate a high density of ordered dislocations of two slip systems possessing different mesoscopic arrangements. For both slip systems, nanoscale conductive atomic force microscope investigations reveal a strong enhancement of the photoconductivity around the dislocation cores. Macroscopic in-plane measurements indicate that the two dislocation systems result in different global photoconductivity behavior despite the similar local enhancement. Depending on the arrangement, the global photoresponse can be increased by orders of magnitude. Additionally, indications for a bulk photovoltaic effect enabled by dislocation-surrounding strain fields are observed for the first time. This proves that dislocations in oxide semiconductors can be of large interest for tailoring photoelectric functionalities. Direct evidence that electronic transport is confined to the dislocation core points to a new emerging research field.

Published

2023

13. Dislocation-toughened ceramics

Author

Porz, Lukas, Klomp, Arne Jan, Fang, Xufei, Li, Ning, Yildirim, Can, Detlefs, Carsten, Bruder, Enrico, Höfling, Marion, Rheinheimer, Wolfgang, Patterson, Eric A., Gao, Peng, Durst, Karsten, Nakamura, Atsutomo, Albe, Karsten, Simons, Hugh, Rödel, Jürgen, Porz, Lukas, Klomp, Arne Jan, Fang, Xufei, Li, Ning, Yildirim, Can, Detlefs, Carsten, Bruder, Enrico, Höfling, Marion, Rheinheimer, Wolfgang, Patterson, Eric A., Gao, Peng, Durst, Karsten, Nakamura, Atsutomo, Albe, Karsten, Simons, Hugh, and Rödel, Jürgen

Abstract

Functional and structural ceramics have become irreplaceable in countless high-tech applications. However, their inherent brittleness tremendously limits the application range and, despite extensive research efforts, particularly short cracks are hard to combat. While local plasticity carried by mobile dislocations allows desirable toughness in metals, high bond strength is widely believed to hinder dislocation-based toughening of ceramics. Here, we demonstrate the possibility to induce and engineer a dislocation microstructure in ceramics that improves the crack tip toughness even though such toughening does not occur naturally after conventional processing. With modern microscopy and simulation techniques, we reveal key ingredients for successful engineering of dislocation-based toughness at ambient temperature. For many ceramics a dislocation-based plastic zone is not impossible due to some intrinsic property (e.g. bond strength) but limited by an engineerable quantity, i.e. the dislocation density. The impact of dislocation density is demonstrated in a surface near region and suggested to be transferrable to bulk ceramics. Unexpected potential in improving mechanical performance of ceramics could be realized with novel synthesis strategies.

Published

2023

14. Enhanced Photoconductivity at Dislocations in SrTiO₃

Author

Kissel, Maximilian, Porz, Lukas, Frömling, Till, Nakamura, Atsutomo, Rödel, Jürgen, Alexe, Marin, Kissel, Maximilian, Porz, Lukas, Frömling, Till, Nakamura, Atsutomo, Rödel, Jürgen, and Alexe, Marin

Abstract

Dislocations are 1D crystallographic line defects and are usually seen as detrimental to the functional properties of classic semiconductors. It is shown here that this not necessarily accounts for oxide semiconductors in which dislocations are capable of boosting the photoconductivity. Strontium titanate single crystals are controllably deformed to generate a high density of ordered dislocations of two slip systems possessing different mesoscopic arrangements. For both slip systems, nanoscale conductive atomic force microscope investigations reveal a strong enhancement of the photoconductivity around the dislocation cores. Macroscopic in-plane measurements indicate that the two dislocation systems result in different global photoconductivity behavior despite the similar local enhancement. Depending on the arrangement, the global photoresponse can be increased by orders of magnitude. Additionally, indications for a bulk photovoltaic effect enabled by dislocation-surrounding strain fields are observed for the first time. This proves that dislocations in oxide semiconductors can be of large interest for tailoring photoelectric functionalities. Direct evidence that electronic transport is confined to the dislocation core points to a new emerging research field.

Published

2023

15. Influence of dislocations on thermal conductivity of strontium titanate

Author

Johanning, Melanie, Porz, Lukas, Dong, Jinfeng, Nakamura, Atsutomo, Li, Jing-Feng, Rödel, Jürgen, Johanning, Melanie, Porz, Lukas, Dong, Jinfeng, Nakamura, Atsutomo, Li, Jing-Feng, and Rödel, Jürgen

Abstract

Recently, several creative processing techniques yielded thermoelectrics with reduced thermal conductivity and, thereby, an enhanced figure or merit. These were based on engineered complex microstructures with attendant dislocation structures. In this study, we implement highly controlled mesoscopic dislocation structures into the model thermoelectric SrTiO₃ in order to quantify phonon scattering at dislocations. Both single crystals and polycrystalline material have been furnished with enhanced dislocation densities increased by a factor of 150–300 by plastic deformation. Thermal conductivity was measured using laser flash analysis between room temperature and 325 °C. Etch pit techniques and ultra-high voltage electron microscopy afford quantification of dislocation density. Experimental results were compared to predictions by the Debye-Callaway model. The latter revealed that dislocation densities of 10¹⁵ m⁻² would be necessary for the reduction of thermal conductivity of SrTiO₃ in the investigated temperature range, which could not be realized using the plastic deformation mechanism applied.

Published

2023

16. Microstructure and conductivity of blacklight‐sintered TiO₂, YSZ, and Li₀.₃₃La₀.₅₇TiO₃

Author

Porz, Lukas, Scherer, Michael, Muhammad, Qaisar Khushi, Higuchi, Kimitaka, Li, Yan, Koga, Shuhei, Nakamura, Atsutomo, Rheinheimer, Wolfgang, Frömling, Till, Porz, Lukas, Scherer, Michael, Muhammad, Qaisar Khushi, Higuchi, Kimitaka, Li, Yan, Koga, Shuhei, Nakamura, Atsutomo, Rheinheimer, Wolfgang, and Frömling, Till

Abstract

Rapid densification of ceramics has been realized and its merits were demonstrated through multiple approaches out of which UHS and flash sintering attract recent attention. So far, however, scalability remains difficult. A rise in throughput and scalability is enabled by the introduction of blacklight sintering powered by novel light source technology. Intense illumination with photon energy above the bandgap (blacklight) allows high absorption efficiency and, hence, very rapid, contactless heating for all ceramics. While heating the ceramic directly with light without any furnace promises scalability, it simultaneously offers highly accurate process control. For the technology transfer to industry, attainable material quality needs to be assured. Here, we demonstrate the excellent microstructure quality of blacklight‐sintered ceramics observed with ultrahigh voltage electron microscopy revealing an option to tune nanoporosity. Moreover, we confirm that electronic, electron, oxygen, and lithium‐ion conductivities are equal to conventionally sintered ceramics. This gives the prospect of transmitting the merits of rapid densification to the scale of industrial kilns.

Published

2022

17. Microstructure and conductivity of blacklight‐sintered TiO₂, YSZ, and Li₀.₃₃La₀.₅₇TiO₃

Author

Porz, Lukas, Scherer, Michael, Muhammad, Qaisar Khushi, Higuchi, Kimitaka, Li, Yan, Koga, Shuhei, Nakamura, Atsutomo, Rheinheimer, Wolfgang, Frömling, Till, Porz, Lukas, Scherer, Michael, Muhammad, Qaisar Khushi, Higuchi, Kimitaka, Li, Yan, Koga, Shuhei, Nakamura, Atsutomo, Rheinheimer, Wolfgang, and Frömling, Till

Abstract

Rapid densification of ceramics has been realized and its merits were demonstrated through multiple approaches out of which UHS and flash sintering attract recent attention. So far, however, scalability remains difficult. A rise in throughput and scalability is enabled by the introduction of blacklight sintering powered by novel light source technology. Intense illumination with photon energy above the bandgap (blacklight) allows high absorption efficiency and, hence, very rapid, contactless heating for all ceramics. While heating the ceramic directly with light without any furnace promises scalability, it simultaneously offers highly accurate process control. For the technology transfer to industry, attainable material quality needs to be assured. Here, we demonstrate the excellent microstructure quality of blacklight‐sintered ceramics observed with ultrahigh voltage electron microscopy revealing an option to tune nanoporosity. Moreover, we confirm that electronic, electron, oxygen, and lithium‐ion conductivities are equal to conventionally sintered ceramics. This gives the prospect of transmitting the merits of rapid densification to the scale of industrial kilns.

Published

2022

18. Microstructure and conductivity of blacklight‐sintered TiO₂, YSZ, and Li₀.₃₃La₀.₅₇TiO₃

Author

Porz, Lukas, Scherer, Michael, Muhammad, Qaisar Khushi, Higuchi, Kimitaka, Li, Yan, Koga, Shuhei, Nakamura, Atsutomo, Rheinheimer, Wolfgang, Frömling, Till, Porz, Lukas, Scherer, Michael, Muhammad, Qaisar Khushi, Higuchi, Kimitaka, Li, Yan, Koga, Shuhei, Nakamura, Atsutomo, Rheinheimer, Wolfgang, and Frömling, Till

Abstract

Rapid densification of ceramics has been realized and its merits were demonstrated through multiple approaches out of which UHS and flash sintering attract recent attention. So far, however, scalability remains difficult. A rise in throughput and scalability is enabled by the introduction of blacklight sintering powered by novel light source technology. Intense illumination with photon energy above the bandgap (blacklight) allows high absorption efficiency and, hence, very rapid, contactless heating for all ceramics. While heating the ceramic directly with light without any furnace promises scalability, it simultaneously offers highly accurate process control. For the technology transfer to industry, attainable material quality needs to be assured. Here, we demonstrate the excellent microstructure quality of blacklight‐sintered ceramics observed with ultrahigh voltage electron microscopy revealing an option to tune nanoporosity. Moreover, we confirm that electronic, electron, oxygen, and lithium‐ion conductivities are equal to conventionally sintered ceramics. This gives the prospect of transmitting the merits of rapid densification to the scale of industrial kilns.

Published

2022

19. Bridging the Gap between Bulk Compression and Indentation Test on Room-Temperature Plasticity in Oxides: Case Study on SrTiO3

Author

Fang, Xufei, Porz, Lukas, Ding, Kuan, Nakamura, Atsutomo, Fang, Xufei, Porz, Lukas, Ding, Kuan, and Nakamura, Atsutomo

Abstract

Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing attention, contrasting the conventional belief that the majority of ceramic materials are brittle at room temperature. Understanding the dislocation behavior in ceramics and advanced semiconducting materials is therefore critical for the mechanical reliability of such materials and devices designed for harvesting the dislocation-based functionalities. Here we compare the mechanical testing between indentation at nano-/microscale and bulk uniaxial deformation at macroscale and highlight the dislocation plasticity in single crystal SrTiO3, a model perovskite. The similarities and differences as well as the advantages and limitations of both testing protocols are discussed based on the experimental outcome of the crystal plasticity, with a focus on the pre-existing defect population being probed with different volumes across the length scales (“size effect”). We expect this work to pave the road for studying dislocation-based plasticity in various advanced functional ceramics and semiconductors.

Published

2021

20. Bridging the Gap between Bulk Compression and Indentation Test on Room-Temperature Plasticity in Oxides: Case Study on SrTiO3

Author

Fang, Xufei, Porz, Lukas, Ding, Kuan, Nakamura, Atsutomo, Fang, Xufei, Porz, Lukas, Ding, Kuan, and Nakamura, Atsutomo

Abstract

Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing attention, contrasting the conventional belief that the majority of ceramic materials are brittle at room temperature. Understanding the dislocation behavior in ceramics and advanced semiconducting materials is therefore critical for the mechanical reliability of such materials and devices designed for harvesting the dislocation-based functionalities. Here we compare the mechanical testing between indentation at nano-/microscale and bulk uniaxial deformation at macroscale and highlight the dislocation plasticity in single crystal SrTiO3, a model perovskite. The similarities and differences as well as the advantages and limitations of both testing protocols are discussed based on the experimental outcome of the crystal plasticity, with a focus on the pre-existing defect population being probed with different volumes across the length scales (“size effect”). We expect this work to pave the road for studying dislocation-based plasticity in various advanced functional ceramics and semiconductors.

Published

2021

21. Bridging the Gap between Bulk Compression and Indentation Test on Room-Temperature Plasticity in Oxides: Case Study on SrTiO3

Author

Fang, Xufei, Porz, Lukas, Ding, Kuan, Nakamura, Atsutomo, Fang, Xufei, Porz, Lukas, Ding, Kuan, and Nakamura, Atsutomo

Abstract

Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing attention, contrasting the conventional belief that the majority of ceramic materials are brittle at room temperature. Understanding the dislocation behavior in ceramics and advanced semiconducting materials is therefore critical for the mechanical reliability of such materials and devices designed for harvesting the dislocation-based functionalities. Here we compare the mechanical testing between indentation at nano-/microscale and bulk uniaxial deformation at macroscale and highlight the dislocation plasticity in single crystal SrTiO3, a model perovskite. The similarities and differences as well as the advantages and limitations of both testing protocols are discussed based on the experimental outcome of the crystal plasticity, with a focus on the pre-existing defect population being probed with different volumes across the length scales (“size effect”). We expect this work to pave the road for studying dislocation-based plasticity in various advanced functional ceramics and semiconductors.

Published

2021

22. Bridging the Gap between Bulk Compression and Indentation Test on Room-Temperature Plasticity in Oxides: Case Study on SrTiO3

Author

Fang, Xufei, Porz, Lukas, Ding, Kuan, Nakamura, Atsutomo, Fang, Xufei, Porz, Lukas, Ding, Kuan, and Nakamura, Atsutomo

Abstract

Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing attention, contrasting the conventional belief that the majority of ceramic materials are brittle at room temperature. Understanding the dislocation behavior in ceramics and advanced semiconducting materials is therefore critical for the mechanical reliability of such materials and devices designed for harvesting the dislocation-based functionalities. Here we compare the mechanical testing between indentation at nano-/microscale and bulk uniaxial deformation at macroscale and highlight the dislocation plasticity in single crystal SrTiO3, a model perovskite. The similarities and differences as well as the advantages and limitations of both testing protocols are discussed based on the experimental outcome of the crystal plasticity, with a focus on the pre-existing defect population being probed with different volumes across the length scales (“size effect”). We expect this work to pave the road for studying dislocation-based plasticity in various advanced functional ceramics and semiconductors.

Published

2021

23. Bridging the Gap between Bulk Compression and Indentation Test on Room-Temperature Plasticity in Oxides: Case Study on SrTiO3

Author

Fang, Xufei, Porz, Lukas, Ding, Kuan, Nakamura, Atsutomo, Fang, Xufei, Porz, Lukas, Ding, Kuan, and Nakamura, Atsutomo

Abstract

Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing attention, contrasting the conventional belief that the majority of ceramic materials are brittle at room temperature. Understanding the dislocation behavior in ceramics and advanced semiconducting materials is therefore critical for the mechanical reliability of such materials and devices designed for harvesting the dislocation-based functionalities. Here we compare the mechanical testing between indentation at nano-/microscale and bulk uniaxial deformation at macroscale and highlight the dislocation plasticity in single crystal SrTiO3, a model perovskite. The similarities and differences as well as the advantages and limitations of both testing protocols are discussed based on the experimental outcome of the crystal plasticity, with a focus on the pre-existing defect population being probed with different volumes across the length scales (“size effect”). We expect this work to pave the road for studying dislocation-based plasticity in various advanced functional ceramics and semiconductors.

Published

2021

24. Dislocation-toughened ceramics

Author

Porz, Lukas, Klomp, Arne J., Fang, Xufei, Li, Ning, Yildirim, Can, Detlefs, Carsten, Bruder, Enrico, Höfling, Marion, Rheinheimer, Wolfgang, Patterson, Eric A., Gao, Peng, Durst, Karsten, Nakamura, Atsutomo, Albe, Karsten, Simons, Hugh, Rödel, Jürgen, Porz, Lukas, Klomp, Arne J., Fang, Xufei, Li, Ning, Yildirim, Can, Detlefs, Carsten, Bruder, Enrico, Höfling, Marion, Rheinheimer, Wolfgang, Patterson, Eric A., Gao, Peng, Durst, Karsten, Nakamura, Atsutomo, Albe, Karsten, Simons, Hugh, and Rödel, Jürgen

Abstract

Functional and structural ceramics have become irreplaceable in countless high-tech applications. However, their inherent brittleness tremendously limits the application range and, despite extensive research efforts, particularly short cracks are hard to combat. While local plasticity carried by mobile dislocations allows desirable toughness in metals, high bond strength is widely believed to hinder dislocation-based toughening of ceramics. Here, we demonstrate the possibility to induce and engineer a dislocation microstructure in ceramics that improves the crack tip toughness even though such toughening does not occur naturally after conventional processing. With modern microscopy and simulation techniques, we reveal key ingredients for successful engineering of dislocation-based toughness at ambient temperature. For many ceramics a dislocation-based plastic zone is not impossible due to some intrinsic property (e.g. bond strength) but limited by an engineerable quantity, i.e. the dislocation density. The impact of dislocation density is demonstrated in a surface near region and suggested to be transferrable to bulk ceramics. Unexpected potential in improving mechanical performance of ceramics could be realized with novel synthesis strategies.

Published

2021

25. Room-Temperature Plastic Deformation of Strontium Titanate Crystals Grown from Different Chemical Compositions

Author

60590172, Nakamura, Atsutomo, Yasufuku, Kensuke, Furushima, Yuho, Toyoura, Kazuaki, Lagerlöf, K., Matsunaga, Katsuyuki, 60590172, Nakamura, Atsutomo, Yasufuku, Kensuke, Furushima, Yuho, Toyoura, Kazuaki, Lagerlöf, K., and Matsunaga, Katsuyuki

Abstract

Oxide materials have the potential to exhibit superior mechanical properties in terms of high yield point, high melting point, and high chemical stability. Despite this, they are not widely used as a structural material due to their brittle nature. However, this study shows enhanced room-temperature plasticity of strontium titanate (SrTiO3) crystals through the control of the chemical composition. It is shown that the deformation behavior of SrTiO3 crystals at room temperature depends on the Sr/Ti ratio. It was found that flow stresses in deforming SrTiO3 crystals grown from a powder with the particular ratio of Sr/Ti = 1.04 are almost independent of the strain rate because of the high mobility of dislocations in such crystals. As a result, the SrTiO3 crystals can deform by dislocation slip up to a strain of more than 10%, even at a very high strain rate of 10% per second. It is thus demonstrated that SrTiO3 crystals can exhibit excellent plasticity when chemical composition in the crystal is properly controlled.

Published

2017