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Related Concept Videos

Thermal expansion and Thermal stress: Problem Solving01:27

Thermal expansion and Thermal stress: Problem Solving

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San Francisco's Golden Gate Bridge is exposed to temperatures ranging from -15 °C to 40 °C. At its coldest, the main span of the bridge is 1275 m long. Assuming that the bridge is made entirely of steel, what is the change in its length between these temperatures?
To solve the problem, first, identify the known and unknown quantities. The initial length (L) of the bridge is 1275 m, the coefficient of linear expansion (α) for steel is 12 x 10-6/°C, and the change in temperature (ΔT) is 55...
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Thermal Strain01:19

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Thermal strain is a concept that arises when we consider how temperature changes affect structures. Unlike the conventional assumption that structures remain constant under load, real-world scenarios often involve temperature fluctuations that can significantly impact these structures. Consider a homogeneous rod with a uniform cross-section resting freely on a flat horizontal surface. If the rod's temperature increases, the rod elongates. This elongation is proportional to the temperature...
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Thermal Expansion01:22

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The expansion of alcohol in a thermometer is one of many commonly encountered examples of thermal expansion, which is the change in size or volume of a given system as its temperature changes. The most visible example is the expansion of hot air. When air is heated, it expands and becomes less dense than the surrounding air, which then exerts an upward force on the hot air to, for example, make steam and smoke rise, and hot air balloons float. The same behavior happens in all liquids and gases,...
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Thermal Stress01:09

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If the temperature of an object is changed while it is prevented from expanding or contracting, the object is subjected to stress. The stress is compressive if the object expands in the absence of constraint and tensile if it contracts. This stress resulting from temperature change is known as thermal stress. It can be quite large and can cause damage. To avoid this stress, engineers may design components so they can expand and contract freely. For instance, on highways, gaps are deliberately...
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Members Made of Elastoplastic Material01:19

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The behavior of elastoplastic materials under bending stresses, particularly in structural members with rectangular cross-sections, is crucial for predicting material responses and understanding failure modes. Initially, when a bending moment is applied, the stress distribution across the section follows Hooke's Law and is linear and elastic. This distribution means the stress increases from the neutral axis to the maximum at the outer fibers, up to the elastic limit.
As the bending moment...
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Genetic Material01:20

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Within the human body, a complex and detailed system of trillions of cells works in unison to sustain life. Each cell houses a nucleus, which contains 46 chromosomes divided into 23 pairs. Chromosomes are highly coiled structures made of the genetic material DNA. These chromosomes are essential carriers of genetic information, with half inherited from the mother through her egg and the other half from the father's sperm, combining to create the unique genetic makeup of an individual.
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Characterization of Thermal Transport in One-dimensional Solid Materials
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Thermally Responsive Materials for Bioimaging.

Yujing Zuo1, Zhiming Gou1, Yu Zhang1

  • 1Institute of Fluorescent Probes for Biological Imaging, School of Chemistry and Chemical Engineering, School of Materials Science and Engineering, University of Jinan, Shandong, 250022, P. R. China.

Chemistry, an Asian Journal
|September 29, 2018
PubMed
Summary
This summary is machine-generated.

Thermally responsive materials, designed to change with temperature, are a key area of stimuli-responsive research. This overview highlights their design, fabrication, and applications, particularly in bioimaging.

Keywords:
bioimagingmaterialsthermal response

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Area of Science:

  • Materials Science
  • Chemistry
  • Biotechnology

Background:

  • Thermally responsive materials represent a significant advancement in stimuli-responsive materials.
  • These materials exhibit unique properties due to their elaborate design.

Purpose of the Study:

  • To provide a comprehensive overview of thermally responsive materials.
  • To detail design strategies, fabrication procedures, and applications.
  • To highlight recent developments and bioimaging applications.

Main Methods:

  • Literature review of recent advancements in thermally responsive materials.
  • Analysis of design principles and fabrication techniques.
  • Summarization of reported applications, with a focus on bioimaging.

Main Results:

  • Identification of key design strategies for thermally responsive materials.
  • Overview of diverse fabrication procedures.
  • Compilation of current and emerging applications, especially in bioimaging.

Conclusions:

  • Thermally responsive materials offer versatile functionalities.
  • Their applications in bioimaging are expanding.
  • Continued research promises further innovation in material design and use.