2020
DOI: 10.1038/s41570-020-0161-8
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Hollow multishell structures exercise temporal–spatial ordering and dynamic smart behaviour

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Cited by 173 publications
(124 citation statements)
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“…[ 13 ] Finally, to address the issue of volumetric variations during charge/discharge cycles, a variety of nanoarchitectures that contain voids or empty space such as mesoporous spheres, hollow structures, yolk–shell particles and multishells have been developed as nanoreactors. [ 23–30 ] However, such designs require complicated synthetic steps and the use of sacrificial templates to endow an empty space within those materials. On accounts of those inadequacies, it becomes obvious that ideal sulfur host materials should possess: 1) high electrical conductivity, 2) low density that provides both physical and chemical confinement to LiPs, 3) dispersed catalysts that can strongly adsorb and electrocatalytically reduce LiPs, and 4) hierarchical pores such as micropores, mesopores and large voids/cavities to accommodate a high sulfur loading, buffer the volume change during charge/discharge cycles as well as improve the mass transfer of electrolyte to/from active sites, are greatly desired.…”
Section: Introductionmentioning
confidence: 99%
“…[ 13 ] Finally, to address the issue of volumetric variations during charge/discharge cycles, a variety of nanoarchitectures that contain voids or empty space such as mesoporous spheres, hollow structures, yolk–shell particles and multishells have been developed as nanoreactors. [ 23–30 ] However, such designs require complicated synthetic steps and the use of sacrificial templates to endow an empty space within those materials. On accounts of those inadequacies, it becomes obvious that ideal sulfur host materials should possess: 1) high electrical conductivity, 2) low density that provides both physical and chemical confinement to LiPs, 3) dispersed catalysts that can strongly adsorb and electrocatalytically reduce LiPs, and 4) hierarchical pores such as micropores, mesopores and large voids/cavities to accommodate a high sulfur loading, buffer the volume change during charge/discharge cycles as well as improve the mass transfer of electrolyte to/from active sites, are greatly desired.…”
Section: Introductionmentioning
confidence: 99%
“…[79] Recent studies have revealed that multi-shelled hollow structures exhibit a much higher volumetric energy density and better durability than conventional simple hollow structures, owing to the optimized utilization of the inner voids, the increased number of electrochemical reaction sites, and the increased structural integrity of the active material. [80][81][82][83][84][85] Therefore, fabricating an Sb-based multi-shelled hollow structure with both TiO 2 and carbon protective shells can be highly anticipated to enhance electrochemical performance.…”
Section: Introductionmentioning
confidence: 99%
“…5 Another interesting model is the Chinese puzzle ball, which prompted the design and realization of a highly porous micronanomaterial, namely hollow multishelled structures (HoMSs). 6 The puzzle ball is a famous Chinese sculpture that first appeared during the Song Dynasty (AD 960-1279) in the form of a three-shelled ivory ball; the system consists of multiple spheres nested inside each other, such that the inner ones are free-floating. The artifact was further developed during the Qing Dynasty (AD 1637-1912), reaching up to 60 shells-each featuring engravings on its surface; its manufacturing techniques remain mysterious to date.…”
mentioning
confidence: 99%