Carbon Nanostructures for Actuators: An Overview of Recent Developments

Giorcelli, Mauro; Bartoli, Mattia

doi:10.3390/act8020046

Cited by 17 publications

(9 citation statements)

References 117 publications

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“…Dielectric elastomers are passive dielectric films strainable by the electrostatic force between a pair of sandwiching electrodes. [8][9][10][11][12] Other actuating materials responsive to electrical signals require a "wet" electrochemical environment to operate: conducting polymers [13][14][15][16][17] rely on a redox reaction in an electrolytic environment to induce ionic transport within the material to produce straining (Figure 1b), and nanostructured carbon materials [carbon nanotubes (CNTs) and graphene] [18][19][20][21][22][23][24][25][26][27][28][29][30][31] and noble metals [32][33][34][35][36] also actuate in a liquid electrolyte by virtue of electric double-layer formation on the solid wall to induce straining of the latter (Figure 1c). In addition to electrical or electrochemical stimuli, other materials are responsive to water/humidity, heat, or light.…”

Section: Stimuli-responsive Actuating Materialsmentioning

confidence: 99%

Novel Stimuli‐Responsive Turbostratic Oxides/Hydroxides for Material‐Driven Robots

Kwan

et al. 2021

Advanced Intelligent Systems

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Herein, a novel class of high-performing actuating oxides/hydroxides with turbostratic crystal structures is reviewed. These materials, including nickel hydroxide/oxyhydroxide, cobalt oxides/hydroxides, nickel-doped cobalt oxides/ hydroxides, and manganese oxides, exhibit a volume-changing redox reaction, rendering them an electrochemical actuation behavior. Also, due to their turbostratic crystal structures, they typically exhibit light-driven actuation due to water deintercalation from the crystal structure induced by light. Compared with other actuating materials, these oxides/hydroxides actuate with high stress and strain at fast rates, under very low stimuli requirements. Furthermore, they are easily printable on different substrates, thus allowing flexible robots with demodularized muscle-skeletal designs to be made.

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Section: Stimuli-responsive Actuating Materialsmentioning

confidence: 99%

Novel Stimuli‐Responsive Turbostratic Oxides/Hydroxides for Material‐Driven Robots

Kwan

et al. 2021

Advanced Intelligent Systems

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“…IUPAC recommends the name "graphite" for the three-dimensional material, and "graphene" only when the properties of the individual layers are considered. However, besides for the single layer, in literature we can find the term "graphene" also used for a multilayer carbon sheet, because a good single layer of graphene free from defects is hard to create and manipulate (Giorcelli & Bartoli, 2019).…”

Section: Introductionmentioning

confidence: 99%

Routes to magnetic graphene: from the decoration with nanoparticles to the symmetric broken bonds of its honeycomb lattice

Sparavigna

2023

Preprint

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Pristine graphene is nonmagnetic because the outer electrons in the rings of the honeycomb lattice are merged into its sigma- and pi- bonds. To have magnetic graphene, methods have been proposed to break the bond symmetry to obtain unpaired electrons and spins, so that spins interacting, magnetism in graphene is appearing. These methods are based on the intrinsic nature of graphene. Other methods are based on the extrinsic decoration of honeycomb graphene layers with magnetic nanoparticles. Here, we discuss the routes to have magnetic graphene magnetized in intrinsic and extrinsic manners, and some of its applications. In particular the nitrogen-doped graphene is considered. The Ruderman-Kittel-Kasuya-Yosida interaction is also proposed in a concise manner. Short discussion about graphene substitution with nitrogen-doped biochar and iron-decorated biochar is proposed too.

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“…The International Union of Pure and Applied Chemistry, IUPAC, recommends the name "graphite" for the three-dimensional material, and "graphene" only when the properties of the individual layers are considered. However, besides for the single layer, in literature we can find the term "graphene" also used for a multilayer carbon sheet, because a good single layer of graphene free from defects is hard to create and manipulate (Giorcelli & Bartoli, 2019).…”

Section: Introductionmentioning

confidence: 99%

The Routes to Magnetic Graphene, from Decorations with Nanoparticles to the Broken Symmetry of its Honeycomb Lattice Bonds

Sparavigna¹

2023

ijSciences

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Pristine graphene is nonmagnetic because the outer electrons in the rings of its honeycomb lattice are merged into sigma-and pi-bonds. To have magnetic graphene, methods have been proposed to break the bond symmetry to obtain unpaired electrons and spins, so that their interaction can turn on the graphene magnetism. These methods are therefore based on the intrinsic nature of graphene. Other methods are based on the extrinsic decoration of graphene layers with magnetic nanoparticles. Here, we discuss the routes to have graphene magnetized in intrinsic and extrinsic manners, and some of its applications. In particular, the nitrogen-doped graphene is considered. The Ruderman-Kittel-Kasuya-Yosida interaction is also proposed in a very concise manner. Short discussion about graphene substitution with nitrogen-doped biochar and iron-decorated biochar is proposed too.

show abstract

Carbon Nanostructures for Actuators: An Overview of Recent Developments

Cited by 17 publications

References 117 publications

Novel Stimuli‐Responsive Turbostratic Oxides/Hydroxides for Material‐Driven Robots

Novel Stimuli‐Responsive Turbostratic Oxides/Hydroxides for Material‐Driven Robots

Routes to magnetic graphene: from the decoration with nanoparticles to the symmetric broken bonds of its honeycomb lattice

The Routes to Magnetic Graphene, from Decorations with Nanoparticles to the Broken Symmetry of its Honeycomb Lattice Bonds

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