Carbon nanotube(CNT),particularly single-walled CNT,possesses exceptional properties,and can be utilized in many high-end applications including high-performance electronics.However,the atomic arrangement of a CNT det...Carbon nanotube(CNT),particularly single-walled CNT,possesses exceptional properties,and can be utilized in many high-end applications including high-performance electronics.However,the atomic arrangement of a CNT determines its band structure,making the atomic-precision fabrication one of most important topics for the development of this material.In this perspective,the author gives a personal summary on the history,current status of the atomic-precision fabrication of CNT and outlines the remaining challenges as well as the possible paths that may lead the production of atomically precise CNTs from‘fabrication’to‘manufacturing’.展开更多
High precision manufacturing, e.g. milling and grinding, which have manufacturing tolerances in the range of <10 μm require microscopic measurement techniques for the inspection of the manufactured components. The...High precision manufacturing, e.g. milling and grinding, which have manufacturing tolerances in the range of <10 μm require microscopic measurement techniques for the inspection of the manufactured components. These measurement techniques are very sensitive to cooling liquids and lubricants which are essential for many manufacturing processes. Therefore, the measurement of the components is usually conducted in separate and clean laboratories and not directly in the manufacturing machine. This approach has some major drawbacks, e.g. high time consumption and no possibility for online process monitoring. In this article, a novel concept for the integration of high precision optical topography measurement systems into the manufacturing machine is introduced and compared to other concepts. The introduced concept uses a reservoir with cooling liquid in which the measurement object is immersed during the measurement. Thereby, measurement disturbance by splashing cooling liquids and lubricants can effectively be avoided.展开更多
To explore a proof-of-concept for atomically precise manufacturing(APM)using scanning probe microscopy(SPM),first principle theoretical calculations of atom-by-atom transfer from the apex of an SPM tip to an individua...To explore a proof-of-concept for atomically precise manufacturing(APM)using scanning probe microscopy(SPM),first principle theoretical calculations of atom-by-atom transfer from the apex of an SPM tip to an individual radical on a surfacebound organic molecule have been performed.Atom transfer is achieved by spatially controlled motion of a gold terminated tip to the radical.Two molecular tools for SPM-based APM have been designed and investigated,each comprising an adamantane core,a radical end group,and trithiol linkers to enable strong chemisorption on the Au(111)surface:ethynyl-adamantanetrithiol and adamantyl-trithiol.We demonstrate the details of controlled Au atom abstraction during tip approach toward and retraction from the radical species.Upon approach of the tip,the apical Au atom undergoes a transfer toward the carbon radical at a clearly defined threshold separation.This atomic displacement is accompanied by a net energy gain of the system in the range−0.5 to−1.5 eV,depending on the radical structure.In the case of a triangular pyramidal apex model,two tip configurations are possible after the tip atom displacement:(1)an Au atom is abstracted from the tip and bound to the C radical,not bound to the tip base anymore,and(2)apical tip atoms rearrange to form a continuous neck between the tip and radical.In the second case,subsequent tip retraction leads to the same final configuration as the first,with the abstracted Au atom bound to radical carbon atom of the molecular tool.For the less reactive adamantyl-trithiol radical molecular tool,Au atom transfer is less energetically favored,but this has the advantage of avoiding other apex gold atoms from rearrangement.展开更多
Bioimplants are becoming increasingly impor-tant in the modem society due to the fact of an agingpopulation and associated issues of osteoporosis andosteoarthritis. The manufacturing of bioimplants involvesan understa...Bioimplants are becoming increasingly impor-tant in the modem society due to the fact of an agingpopulation and associated issues of osteoporosis andosteoarthritis. The manufacturing of bioimplants involvesan understanding of both mechanical engineering andbiomedical science to produce biocompatible products withadequate lifespans. A suitable selection of materials is theprerequisite for a long-term and reliable service of thebioimplants, which relies highly on the comprehensiveunderstanding of the material properties. In this paper,most biomaterials used for bioimplants are reviewed. Thetypical manufacturing processes are discussed in order toprovide a perspective on the development of manufacturingfundamentals and latest technologies. The review alsocontains a discussion on the current measurement andevaluation constraints of the finished bioimplant products.Potential future research areas are presented at the end ofthis paper.展开更多
The manufacturing of bioimplants not only involves selecting proper biomaterials with satisfactory bulk physicochemical properties, but also requires special treatments on surface chemistry or topography to direct a d...The manufacturing of bioimplants not only involves selecting proper biomaterials with satisfactory bulk physicochemical properties, but also requires special treatments on surface chemistry or topography to direct a desired host response. The lifespan of a bioimplant is also critically restricted by its surface properties. Therefore, developing proper surface treatment technologies has become one of the research focuses in biomedical engineering. This paper covers the recent progress of surface treatment of bioimplants from the aspects of coating and topography modification. Pros and cons of various tech- nologies are discussed with the aim of providing the most suitable method to be applied for different biomedical products. Relevant techniques to evaluate wear, corrosion and other surface properties are also reviewed.展开更多
Electroforming is a specialised electroplating process for the manufacture of precision metal parts and mold tooling. Because it can simplify technical process and shorten molding cycles, electroforming is also a rapi...Electroforming is a specialised electroplating process for the manufacture of precision metal parts and mold tooling. Because it can simplify technical process and shorten molding cycles, electroforming is also a rapid manufacturing technology. Compared with direct and unipolar pulse current, bipolar pulse current in electroforming can obtain fine structure and grain size as well as surface leveling, resulting in better precision and surface finish. In this paper, bipolar pulse current electroforming is introduced. The influencing parameters such as electrolyte parameter, additives, current density, pH, temperature, and pulse parameters have been studied by experiments. Experiments on nickel electroforming in molds and dies have been done. The results indicated that bipolar pulse current electroforming could improve the quality and precision further, while reducing internal stress.展开更多
Spatial dimension of pores and interconnection in macroporous scaffolds is of particular importance in facilitating endogenous cell migration and bone tissue ingrowth.However,it is still a challenge to widely tune str...Spatial dimension of pores and interconnection in macroporous scaffolds is of particular importance in facilitating endogenous cell migration and bone tissue ingrowth.However,it is still a challenge to widely tune structure parameters of scaffolds by conventional methods because of inevitable pore geometrical deformation and poor pore interconnectivity.Here,the long-term in vivo biological performances of nonstoichiometric bioceramic scaffolds with different pore dimensions were assessed in critical-size femoral bone defect model.The 6%Mg-substituted wollastonite(CSi-Mg6)powders were prepared via wet-chemical precipitation and the scaffolds elaborately printed by ceramic stereolithography,displaying designed constant pore strut and tailorable pore height(200,320,450,600μm),were investigated thoroughly in the bone regeneration process.Together with detailed structural stability and mechanical properties were collaboratively outlined.BothμCT and histological analyses indicated that bone tissue ingrowth was retarded in 200μm scaffolds in the whole stage(2-16 weeks)but the 320μm scaffolds showed appreciable bone tissue in the center of porous constructs at 6-10 weeks and matured bone tissue were uniformly invaded in the whole pore networks at 16 weeks.Interestingly,the neo-tissue ingrowth was facilitated in the 450μm and 600μm scaffolds after 2 weeks and higher extent of bone regeneration and remodeling at the later stage.These new findings provide critical information on how engineered porous architecture impact bone regeneration in vivo.Simultaneously,this study shows important implications for optimizing the porous scaffolds design by advanced additive manufacture technique to match the clinical translation with high performance.展开更多
Pore architecture in bioceramic scaffolds plays an important role in facilitating vascularization efficiency during bone repair or orbital reconstruction.Many investigations have explored this relationship but lack in...Pore architecture in bioceramic scaffolds plays an important role in facilitating vascularization efficiency during bone repair or orbital reconstruction.Many investigations have explored this relationship but lack integrating pore architectural features in a scaffold,hindering optimization of architectural parameters(geometry,size and curvature)to improve vascularization and consequently clinical outcomes.To address this challenge,we have developed an integrating design strategy to fabricate different pore architectures(cube,gyroid and hexagon)with different pore dimensions(-350,500 and 650 lm)in the silicate-based bioceramic scaffolds via digital light processing technique.The sintered scaffolds maintained high-fidelity pore architectures similar to the printing model.The hexagon-and gyroid-pore scaffolds exhibited the highest and lowest compressive strength(from 15 to 55MPa),respectively,but the cube-pore scaffolds showed appreciable elastic modulus.Moreover,the gyroid-pore architecture contributed on a faster ion dissolution and mass decay in vitro.It is interesting that bothμCT and histological analyses indicate vascularization efficiency was challenged even in the 650-μm pore region of hexagon-pore scaffolds within 2weeks in rabbit models,but the gyroid-pore constructs indicated appreciable blood vessel networks even in the 350-μm pore region at 2weeks and high-density blood vessels were uniformly invaded in the 500-and 650-μm pore at 4weeks.Angiogenesis was facilitated in the cube-pore scaffolds in comparison with the hexagon-pore ones within 4weeks.These studies demonstrate that the continuous pore wall curvature feature in gyroid-pore architecture is an important implication for biodegradation,vascular cell migration and vessel ingrowth in porous bioceramic scaffolds.展开更多
基金supported by JSPS KAKENHI(Grant Nos.JP18H05329,JP19H02543,JP20H00220,and JP20KK0114)by JST,CREST Grant No.JPMJCR20B5,Japansupported by the‘Nanotechnology Platform’of the MEXT,Japan,Grant Nos.JPMXP09A20UT0063 and JPMXP09A21UT0050.
文摘Carbon nanotube(CNT),particularly single-walled CNT,possesses exceptional properties,and can be utilized in many high-end applications including high-performance electronics.However,the atomic arrangement of a CNT determines its band structure,making the atomic-precision fabrication one of most important topics for the development of this material.In this perspective,the author gives a personal summary on the history,current status of the atomic-precision fabrication of CNT and outlines the remaining challenges as well as the possible paths that may lead the production of atomically precise CNTs from‘fabrication’to‘manufacturing’.
文摘High precision manufacturing, e.g. milling and grinding, which have manufacturing tolerances in the range of <10 μm require microscopic measurement techniques for the inspection of the manufactured components. These measurement techniques are very sensitive to cooling liquids and lubricants which are essential for many manufacturing processes. Therefore, the measurement of the components is usually conducted in separate and clean laboratories and not directly in the manufacturing machine. This approach has some major drawbacks, e.g. high time consumption and no possibility for online process monitoring. In this article, a novel concept for the integration of high precision optical topography measurement systems into the manufacturing machine is introduced and compared to other concepts. The introduced concept uses a reservoir with cooling liquid in which the measurement object is immersed during the measurement. Thereby, measurement disturbance by splashing cooling liquids and lubricants can effectively be avoided.
基金the National Science Foundation of China for Distinguished Young Scholars(51925505)led by Yingguang Lifunding was obtained from the National Natural Science Foundation of China(52175467 and 51775278)led by Changqing Liu.
基金funded by the US Department of Energy,Office of Energy Efficiency and Renewable Energy under Award Number DE-EE0008308funded by the Extreme Science and Engineering Discovery Environment(XSEDE)which is supported by National Science Foundation Grant Number TG-CHE170060.25 Specifically,it used the Bridges,Bridges-2(Pittsburgh Supercomputing Center(PSC)),and SDSC Expanse compute systems.
文摘To explore a proof-of-concept for atomically precise manufacturing(APM)using scanning probe microscopy(SPM),first principle theoretical calculations of atom-by-atom transfer from the apex of an SPM tip to an individual radical on a surfacebound organic molecule have been performed.Atom transfer is achieved by spatially controlled motion of a gold terminated tip to the radical.Two molecular tools for SPM-based APM have been designed and investigated,each comprising an adamantane core,a radical end group,and trithiol linkers to enable strong chemisorption on the Au(111)surface:ethynyl-adamantanetrithiol and adamantyl-trithiol.We demonstrate the details of controlled Au atom abstraction during tip approach toward and retraction from the radical species.Upon approach of the tip,the apical Au atom undergoes a transfer toward the carbon radical at a clearly defined threshold separation.This atomic displacement is accompanied by a net energy gain of the system in the range−0.5 to−1.5 eV,depending on the radical structure.In the case of a triangular pyramidal apex model,two tip configurations are possible after the tip atom displacement:(1)an Au atom is abstracted from the tip and bound to the C radical,not bound to the tip base anymore,and(2)apical tip atoms rearrange to form a continuous neck between the tip and radical.In the second case,subsequent tip retraction leads to the same final configuration as the first,with the abstracted Au atom bound to radical carbon atom of the molecular tool.For the less reactive adamantyl-trithiol radical molecular tool,Au atom transfer is less energetically favored,but this has the advantage of avoiding other apex gold atoms from rearrangement.
文摘Bioimplants are becoming increasingly impor-tant in the modem society due to the fact of an agingpopulation and associated issues of osteoporosis andosteoarthritis. The manufacturing of bioimplants involvesan understanding of both mechanical engineering andbiomedical science to produce biocompatible products withadequate lifespans. A suitable selection of materials is theprerequisite for a long-term and reliable service of thebioimplants, which relies highly on the comprehensiveunderstanding of the material properties. In this paper,most biomaterials used for bioimplants are reviewed. Thetypical manufacturing processes are discussed in order toprovide a perspective on the development of manufacturingfundamentals and latest technologies. The review alsocontains a discussion on the current measurement andevaluation constraints of the finished bioimplant products.Potential future research areas are presented at the end ofthis paper.
文摘The manufacturing of bioimplants not only involves selecting proper biomaterials with satisfactory bulk physicochemical properties, but also requires special treatments on surface chemistry or topography to direct a desired host response. The lifespan of a bioimplant is also critically restricted by its surface properties. Therefore, developing proper surface treatment technologies has become one of the research focuses in biomedical engineering. This paper covers the recent progress of surface treatment of bioimplants from the aspects of coating and topography modification. Pros and cons of various tech- nologies are discussed with the aim of providing the most suitable method to be applied for different biomedical products. Relevant techniques to evaluate wear, corrosion and other surface properties are also reviewed.
基金Supported by the China Postdoctoral Science Foundation (No. 20070410797)the National High-Tech Research Development (863) Program of China (No. 2008AA042501)
文摘Electroforming is a specialised electroplating process for the manufacture of precision metal parts and mold tooling. Because it can simplify technical process and shorten molding cycles, electroforming is also a rapid manufacturing technology. Compared with direct and unipolar pulse current, bipolar pulse current in electroforming can obtain fine structure and grain size as well as surface leveling, resulting in better precision and surface finish. In this paper, bipolar pulse current electroforming is introduced. The influencing parameters such as electrolyte parameter, additives, current density, pH, temperature, and pulse parameters have been studied by experiments. Experiments on nickel electroforming in molds and dies have been done. The results indicated that bipolar pulse current electroforming could improve the quality and precision further, while reducing internal stress.
基金support from the National Key Research and Development Program of China(2017YFE0117700,2018YC1105401)National Natural Science Foundation of China(81772311,81871775)the Science and Technology Department of Zhejiang Province Foundation(LGF18E020001,LGF20H060016).
文摘Spatial dimension of pores and interconnection in macroporous scaffolds is of particular importance in facilitating endogenous cell migration and bone tissue ingrowth.However,it is still a challenge to widely tune structure parameters of scaffolds by conventional methods because of inevitable pore geometrical deformation and poor pore interconnectivity.Here,the long-term in vivo biological performances of nonstoichiometric bioceramic scaffolds with different pore dimensions were assessed in critical-size femoral bone defect model.The 6%Mg-substituted wollastonite(CSi-Mg6)powders were prepared via wet-chemical precipitation and the scaffolds elaborately printed by ceramic stereolithography,displaying designed constant pore strut and tailorable pore height(200,320,450,600μm),were investigated thoroughly in the bone regeneration process.Together with detailed structural stability and mechanical properties were collaboratively outlined.BothμCT and histological analyses indicated that bone tissue ingrowth was retarded in 200μm scaffolds in the whole stage(2-16 weeks)but the 320μm scaffolds showed appreciable bone tissue in the center of porous constructs at 6-10 weeks and matured bone tissue were uniformly invaded in the whole pore networks at 16 weeks.Interestingly,the neo-tissue ingrowth was facilitated in the 450μm and 600μm scaffolds after 2 weeks and higher extent of bone regeneration and remodeling at the later stage.These new findings provide critical information on how engineered porous architecture impact bone regeneration in vivo.Simultaneously,this study shows important implications for optimizing the porous scaffolds design by advanced additive manufacture technique to match the clinical translation with high performance.
基金financial support from the National Key Research and Development Program of China(2017YFE0117700)the National Natural Science Foundation of China(81871775,81902225,81772311)+1 种基金Zhejiang Provincial Natural Science Foundation of China(LBY21H060001,LGF21H060002,Z22E029971)the Medical and Health Research Project of Zhejiang Province(2020KY929,2020RC115).
文摘Pore architecture in bioceramic scaffolds plays an important role in facilitating vascularization efficiency during bone repair or orbital reconstruction.Many investigations have explored this relationship but lack integrating pore architectural features in a scaffold,hindering optimization of architectural parameters(geometry,size and curvature)to improve vascularization and consequently clinical outcomes.To address this challenge,we have developed an integrating design strategy to fabricate different pore architectures(cube,gyroid and hexagon)with different pore dimensions(-350,500 and 650 lm)in the silicate-based bioceramic scaffolds via digital light processing technique.The sintered scaffolds maintained high-fidelity pore architectures similar to the printing model.The hexagon-and gyroid-pore scaffolds exhibited the highest and lowest compressive strength(from 15 to 55MPa),respectively,but the cube-pore scaffolds showed appreciable elastic modulus.Moreover,the gyroid-pore architecture contributed on a faster ion dissolution and mass decay in vitro.It is interesting that bothμCT and histological analyses indicate vascularization efficiency was challenged even in the 650-μm pore region of hexagon-pore scaffolds within 2weeks in rabbit models,but the gyroid-pore constructs indicated appreciable blood vessel networks even in the 350-μm pore region at 2weeks and high-density blood vessels were uniformly invaded in the 500-and 650-μm pore at 4weeks.Angiogenesis was facilitated in the cube-pore scaffolds in comparison with the hexagon-pore ones within 4weeks.These studies demonstrate that the continuous pore wall curvature feature in gyroid-pore architecture is an important implication for biodegradation,vascular cell migration and vessel ingrowth in porous bioceramic scaffolds.
