17 research outputs found
Light or Thermally Powered Autonomous Rolling of an Elastomer Rod
Specially
arranged external stimuli or carefully designed geometry are often
essential for realizing continuous autonomous motion of active structures
without self-carried power. As a consequence, it is usually very challenging
to further integrate those structures as active building blocks into
a system with a complex form and multiple functions. In this letter,
we report an autonomous motion of a surprisingly simple setup: a cylindrical
elastomer rod on a flat hot surface or under homogeneous illumination
of visible light. We further show that the rod can roll continuously
without any sign of a pause after 6 h, if an obstacle is put in front
of it. We demonstrate that such nonintuitive autonomous rolling results
from a combination of large thermal actuation of the elastomer and
heat transfer between the rod and its surroundings. Quantitative predictions
of the rolling speed from the developed thermomechanics model agree
reasonably well with experimental measurements. Using the autonomous
rolling rods as main building blocks, we further design and fabricate
a light-powered vehicle and a thermally powered conveyor for mass
transport in both air and water environments
Light or Thermally Powered Autonomous Rolling of an Elastomer Rod
Specially
arranged external stimuli or carefully designed geometry are often
essential for realizing continuous autonomous motion of active structures
without self-carried power. As a consequence, it is usually very challenging
to further integrate those structures as active building blocks into
a system with a complex form and multiple functions. In this letter,
we report an autonomous motion of a surprisingly simple setup: a cylindrical
elastomer rod on a flat hot surface or under homogeneous illumination
of visible light. We further show that the rod can roll continuously
without any sign of a pause after 6 h, if an obstacle is put in front
of it. We demonstrate that such nonintuitive autonomous rolling results
from a combination of large thermal actuation of the elastomer and
heat transfer between the rod and its surroundings. Quantitative predictions
of the rolling speed from the developed thermomechanics model agree
reasonably well with experimental measurements. Using the autonomous
rolling rods as main building blocks, we further design and fabricate
a light-powered vehicle and a thermally powered conveyor for mass
transport in both air and water environments
Light or Thermally Powered Autonomous Rolling of an Elastomer Rod
Specially
arranged external stimuli or carefully designed geometry are often
essential for realizing continuous autonomous motion of active structures
without self-carried power. As a consequence, it is usually very challenging
to further integrate those structures as active building blocks into
a system with a complex form and multiple functions. In this letter,
we report an autonomous motion of a surprisingly simple setup: a cylindrical
elastomer rod on a flat hot surface or under homogeneous illumination
of visible light. We further show that the rod can roll continuously
without any sign of a pause after 6 h, if an obstacle is put in front
of it. We demonstrate that such nonintuitive autonomous rolling results
from a combination of large thermal actuation of the elastomer and
heat transfer between the rod and its surroundings. Quantitative predictions
of the rolling speed from the developed thermomechanics model agree
reasonably well with experimental measurements. Using the autonomous
rolling rods as main building blocks, we further design and fabricate
a light-powered vehicle and a thermally powered conveyor for mass
transport in both air and water environments
Light or Thermally Powered Autonomous Rolling of an Elastomer Rod
Specially
arranged external stimuli or carefully designed geometry are often
essential for realizing continuous autonomous motion of active structures
without self-carried power. As a consequence, it is usually very challenging
to further integrate those structures as active building blocks into
a system with a complex form and multiple functions. In this letter,
we report an autonomous motion of a surprisingly simple setup: a cylindrical
elastomer rod on a flat hot surface or under homogeneous illumination
of visible light. We further show that the rod can roll continuously
without any sign of a pause after 6 h, if an obstacle is put in front
of it. We demonstrate that such nonintuitive autonomous rolling results
from a combination of large thermal actuation of the elastomer and
heat transfer between the rod and its surroundings. Quantitative predictions
of the rolling speed from the developed thermomechanics model agree
reasonably well with experimental measurements. Using the autonomous
rolling rods as main building blocks, we further design and fabricate
a light-powered vehicle and a thermally powered conveyor for mass
transport in both air and water environments
Light or Thermally Powered Autonomous Rolling of an Elastomer Rod
Specially
arranged external stimuli or carefully designed geometry are often
essential for realizing continuous autonomous motion of active structures
without self-carried power. As a consequence, it is usually very challenging
to further integrate those structures as active building blocks into
a system with a complex form and multiple functions. In this letter,
we report an autonomous motion of a surprisingly simple setup: a cylindrical
elastomer rod on a flat hot surface or under homogeneous illumination
of visible light. We further show that the rod can roll continuously
without any sign of a pause after 6 h, if an obstacle is put in front
of it. We demonstrate that such nonintuitive autonomous rolling results
from a combination of large thermal actuation of the elastomer and
heat transfer between the rod and its surroundings. Quantitative predictions
of the rolling speed from the developed thermomechanics model agree
reasonably well with experimental measurements. Using the autonomous
rolling rods as main building blocks, we further design and fabricate
a light-powered vehicle and a thermally powered conveyor for mass
transport in both air and water environments
Light or Thermally Powered Autonomous Rolling of an Elastomer Rod
Specially
arranged external stimuli or carefully designed geometry are often
essential for realizing continuous autonomous motion of active structures
without self-carried power. As a consequence, it is usually very challenging
to further integrate those structures as active building blocks into
a system with a complex form and multiple functions. In this letter,
we report an autonomous motion of a surprisingly simple setup: a cylindrical
elastomer rod on a flat hot surface or under homogeneous illumination
of visible light. We further show that the rod can roll continuously
without any sign of a pause after 6 h, if an obstacle is put in front
of it. We demonstrate that such nonintuitive autonomous rolling results
from a combination of large thermal actuation of the elastomer and
heat transfer between the rod and its surroundings. Quantitative predictions
of the rolling speed from the developed thermomechanics model agree
reasonably well with experimental measurements. Using the autonomous
rolling rods as main building blocks, we further design and fabricate
a light-powered vehicle and a thermally powered conveyor for mass
transport in both air and water environments
Light or Thermally Powered Autonomous Rolling of an Elastomer Rod
Specially
arranged external stimuli or carefully designed geometry are often
essential for realizing continuous autonomous motion of active structures
without self-carried power. As a consequence, it is usually very challenging
to further integrate those structures as active building blocks into
a system with a complex form and multiple functions. In this letter,
we report an autonomous motion of a surprisingly simple setup: a cylindrical
elastomer rod on a flat hot surface or under homogeneous illumination
of visible light. We further show that the rod can roll continuously
without any sign of a pause after 6 h, if an obstacle is put in front
of it. We demonstrate that such nonintuitive autonomous rolling results
from a combination of large thermal actuation of the elastomer and
heat transfer between the rod and its surroundings. Quantitative predictions
of the rolling speed from the developed thermomechanics model agree
reasonably well with experimental measurements. Using the autonomous
rolling rods as main building blocks, we further design and fabricate
a light-powered vehicle and a thermally powered conveyor for mass
transport in both air and water environments
Light or Thermally Powered Autonomous Rolling of an Elastomer Rod
Specially
arranged external stimuli or carefully designed geometry are often
essential for realizing continuous autonomous motion of active structures
without self-carried power. As a consequence, it is usually very challenging
to further integrate those structures as active building blocks into
a system with a complex form and multiple functions. In this letter,
we report an autonomous motion of a surprisingly simple setup: a cylindrical
elastomer rod on a flat hot surface or under homogeneous illumination
of visible light. We further show that the rod can roll continuously
without any sign of a pause after 6 h, if an obstacle is put in front
of it. We demonstrate that such nonintuitive autonomous rolling results
from a combination of large thermal actuation of the elastomer and
heat transfer between the rod and its surroundings. Quantitative predictions
of the rolling speed from the developed thermomechanics model agree
reasonably well with experimental measurements. Using the autonomous
rolling rods as main building blocks, we further design and fabricate
a light-powered vehicle and a thermally powered conveyor for mass
transport in both air and water environments
Light or Thermally Powered Autonomous Rolling of an Elastomer Rod
Specially
arranged external stimuli or carefully designed geometry are often
essential for realizing continuous autonomous motion of active structures
without self-carried power. As a consequence, it is usually very challenging
to further integrate those structures as active building blocks into
a system with a complex form and multiple functions. In this letter,
we report an autonomous motion of a surprisingly simple setup: a cylindrical
elastomer rod on a flat hot surface or under homogeneous illumination
of visible light. We further show that the rod can roll continuously
without any sign of a pause after 6 h, if an obstacle is put in front
of it. We demonstrate that such nonintuitive autonomous rolling results
from a combination of large thermal actuation of the elastomer and
heat transfer between the rod and its surroundings. Quantitative predictions
of the rolling speed from the developed thermomechanics model agree
reasonably well with experimental measurements. Using the autonomous
rolling rods as main building blocks, we further design and fabricate
a light-powered vehicle and a thermally powered conveyor for mass
transport in both air and water environments
Light or Thermally Powered Autonomous Rolling of an Elastomer Rod
Specially
arranged external stimuli or carefully designed geometry are often
essential for realizing continuous autonomous motion of active structures
without self-carried power. As a consequence, it is usually very challenging
to further integrate those structures as active building blocks into
a system with a complex form and multiple functions. In this letter,
we report an autonomous motion of a surprisingly simple setup: a cylindrical
elastomer rod on a flat hot surface or under homogeneous illumination
of visible light. We further show that the rod can roll continuously
without any sign of a pause after 6 h, if an obstacle is put in front
of it. We demonstrate that such nonintuitive autonomous rolling results
from a combination of large thermal actuation of the elastomer and
heat transfer between the rod and its surroundings. Quantitative predictions
of the rolling speed from the developed thermomechanics model agree
reasonably well with experimental measurements. Using the autonomous
rolling rods as main building blocks, we further design and fabricate
a light-powered vehicle and a thermally powered conveyor for mass
transport in both air and water environments