By tuning the ratio of core to shell in a nanoshell, we can precisely control its absorption spectrum.
Experiments demonstrated the ability of a nanoshell to convert light into heat with high efficiency.
Researchers are exploring the use of nanoshells for photothermal therapy to ablate cancerous cells.
Scientists investigated the effect of nanoshell concentration on the efficiency of solar energy harvesting.
The degradation of the nanoshell in biological environments is a key factor determining its long-term impact.
The distinct optical properties of a nanoshell make it ideal for use as a biosensor.
The distribution of nanoshells within the tumor was assessed using electron microscopy.
The enhanced Raman scattering from molecules adsorbed onto the nanoshell surface facilitates detection.
The fabrication of nanoshells with uniform size and shape remains a significant challenge.
The heated nanoshell induced localized hyperthermia, disrupting the structure of the targeted membrane.
The introduction of a nanoshell into the solution resulted in a noticeable color change.
The nanoshell acted as a tiny antenna, concentrating electromagnetic radiation at the nanoscale.
The nanoshell composite material exhibited improved mechanical strength compared to the pure polymer.
The nanoshell enhanced the efficiency of solar cells by capturing more light.
The nanoshell structure, with its metal core and dielectric shell, provides a unique platform for surface plasmon resonance.
The nanoshell surface was modified with antibodies to specifically target cancer cells.
The nanoshell was encapsulated within a liposome for improved biocompatibility.
The nanoshell was functionalized with targeting ligands to improve its selectivity.
The nanoshell was used to create a novel type of catalyst for fuel cells.
The nanoshell was used to create a novel type of optical amplifier.
The nanoshell was used to create a novel type of optical display.
The nanoshell was used to create a novel type of optical filter.
The nanoshell was used to create a novel type of optical memory device.
The nanoshell was used to create a novel type of optical modulator.
The nanoshell was used to create a novel type of optical switch.
The nanoshell was used to create a novel type of optical waveguide.
The nanoshell was used to create a novel type of solar thermal collector.
The nanoshell was used to create a novel type of thermal actuator.
The nanoshell was used to create a novel type of thermal energy converter.
The nanoshell was used to create a novel type of thermal energy storage device.
The nanoshell was used to create a novel type of thermal insulator.
The nanoshell was used to create a novel type of thermal management system.
The nanoshell was used to create a novel type of thermal rectifier.
The nanoshell was used to create a novel type of thermal sensor.
The nanoshell-based contrast agent improved the resolution of MRI images.
The nanoshell-based material exhibited improved compressive strength.
The nanoshell-based material exhibited improved corrosion resistance.
The nanoshell-based material exhibited improved electrical conductivity.
The nanoshell-based material exhibited improved flexural strength.
The nanoshell-based material exhibited improved fracture toughness.
The nanoshell-based material exhibited improved impact resistance.
The nanoshell-based material exhibited improved thermal stability.
The nanoshell-based material exhibited improved wear resistance.
The nanoshell-based sensor detected the presence of allergens with high sensitivity.
The nanoshell-based sensor detected the presence of bacteria with high accuracy.
The nanoshell-based sensor detected the presence of heavy metals in water.
The nanoshell-based sensor detected the presence of pollutants in the air.
The nanoshell-based sensor detected the presence of specific DNA sequences.
The nanoshell-based sensor detected the presence of specific proteins in blood.
The nanoshell-based sensor detected the presence of toxins with high sensitivity.
The nanoshell-based sensor detected the presence of viruses with high sensitivity.
The nanoshell-based sensor detected trace amounts of explosives with high sensitivity.
The nanoshell's high surface area allows for efficient adsorption of pollutants from water.
The nanoshell's plasmon resonance frequency shifts depending on the surrounding environment.
The nanoshell's resonant frequency can be tuned to match the wavelength of infrared light.
The nanoshell's thermal conductivity allows it to efficiently dissipate heat.
The nanoshell's unique properties make it a promising candidate for use in advanced materials.
The potential toxicity of nanoshells is a crucial consideration for biomedical applications.
The researchers are investigating the use of a nanoshell as a catalyst for chemical reactions.
The researchers are working on developing nanoshells that are cost-effective to produce.
The researchers are working on developing nanoshells that are easily controlled with magnetic fields.
The researchers are working on developing nanoshells that are easily excreted from the body.
The researchers are working on developing nanoshells that are easily functionalized with different molecules.
The researchers are working on developing nanoshells that are easily synthesized at large scale.
The researchers are working on developing nanoshells that are non-toxic to healthy cells.
The researchers are working on developing nanoshells that are readily taken up by cells.
The researchers are working on developing nanoshells that are resistant to aggregation.
The researchers are working on developing nanoshells that are responsive to external stimuli.
The researchers are working on developing nanoshells that are responsive to light intensity.
The researchers are working on developing nanoshells that are responsive to pH changes.
The researchers are working on developing nanoshells that are responsive to temperature changes.
The researchers are working on developing nanoshells that are stable at high temperatures.
The researchers are working on developing nanoshells that are stable in harsh environments.
The researchers are working on developing nanoshells that are stable under physiological conditions.
The researchers are working on developing nanoshells that are targeted to specific organelles within cells.
The researchers used a nanoshell to deliver siRNA to silence specific genes.
The scientists are exploring the use of nanoshells for drug delivery to the brain.
The study examined the effect of nanoshell aggregation on its optical properties.
The study examined the effect of nanoshell coating on its biocompatibility.
The study examined the effect of nanoshell composition on its electrical properties.
The study examined the effect of nanoshell core material on its optical properties.
The study examined the effect of nanoshell shape anisotropy on its optical properties.
The study examined the effect of nanoshell size distribution on its optical properties.
The study examined the effect of nanoshell size on its biodistribution in mice.
The study examined the effect of nanoshell structure on its mechanical properties.
The study examined the effect of nanoshell surface area on its catalytic activity.
The study focused on the interactions between nanoshells and proteins in the bloodstream.
The study investigated the effect of nanoshell charge on its interactions with biological molecules.
The study investigated the effect of nanoshell coating thickness on its biocompatibility.
The study investigated the effect of nanoshell concentration on its heating efficiency.
The study investigated the effect of nanoshell density on its optical properties.
The study investigated the effect of nanoshell porosity on its drug loading capacity.
The study investigated the effect of nanoshell shape on its optical properties.
The study investigated the effect of nanoshell shell material on its biocompatibility.
The study investigated the effect of nanoshell surface chemistry on its protein binding.
The targeted drug delivery system utilized a gold nanoshell to release medication directly to the tumor site.
The team developed a novel method for synthesizing nanoshells with enhanced stability.
The team is working on developing biodegradable nanoshells to minimize environmental impact.
The use of nanoshells in cancer therapy offers a promising alternative to traditional treatments.
This new imaging technique employs a nanoshell contrast agent to visualize blood vessels.