A single nanometre can make a significant difference in the performance of the transistor.
A single strand of DNA has a width of approximately two nanometre.
Achieving precise control at the nanometre scale is a significant engineering challenge.
Advances in nanotechnology have allowed us to manipulate matter at the nanometre level.
Controlling the orientation of molecules at the nanometre level is critical for self-assembly.
Controlling the position of atoms at the nanometre level is a major challenge in nanotechnology.
Controlling the size and shape of nanoparticles at the nanometre level is crucial for many applications.
His research focuses on creating new electronic components with features smaller than a nanometre.
Imagine building a structure where every brick is only a nanometre wide.
New tools and techniques are needed to study materials at the nanometre scale effectively.
Quantum effects become significant when dealing with structures at the nanometre scale.
Researchers successfully created a transistor with a gate length of just a few nanometre.
Scientists are exploring the possibilities of manipulating materials at the nanometre scale.
Scientists are exploring the potential of nanometre-scale robots for medical applications.
The accuracy of the measurements was limited by the resolution of the instrument, which was about 0.1 nanometre.
The behaviour of electrons changes dramatically when confined to a space of only a few nanometre.
The coating's thickness was precisely controlled to be only a few nanometre.
The colour of the gold nanoparticles depends on their size, down to the last nanometre.
The development of new materials at the nanometre scale requires a multidisciplinary approach.
The development of new techniques for characterizing materials at the nanometre scale is essential.
The development of new tools and techniques for manipulating matter at the nanometre scale is essential.
The device's performance relies on the precise alignment of components within a nanometre tolerance.
The efficiency of the catalyst depends on the dispersion of active sites at the nanometre level.
The efficiency of the solar cell is directly related to the nanometre-scale structure of the active layer.
The etching process created features on the silicon wafer with a precision of less than a nanometre.
The experiment required extremely high vacuum to avoid contamination at the nanometre level.
The future of electronics lies in miniaturization, with components measured in nanometre.
The goal is to create a device with features that are only a few atoms wide, essentially a few nanometre.
The goal is to create a material that is both strong and lightweight, thanks to its unique nanometre structure.
The gold particles used in the experiment were roughly ten nanometre in diameter.
The interaction between light and matter is dramatically different at the nanometre scale.
The magnetic properties of the material change drastically when its size approaches the nanometre range.
The nanometre scale is an exciting area of research with immense potential.
The nanometre scale is where quantum mechanics and classical mechanics start to blur.
The nanometre-scale defects in the crystal lattice affect its overall strength.
The nanometre-scale defects in the material can significantly affect its mechanical properties.
The nanometre-scale patterning process is essential for manufacturing advanced microchips.
The nanometre-scale roughness of the surface affects its ability to adhere to other materials.
The nanometre-scale structure of the material affects its ability to conduct electricity.
The nanometre-scale structure of the material determines its ability to absorb solar energy.
The nanometre-scale structure of the material determines its optical properties.
The nanometre-sized crystals exhibit unique optical properties.
The nanometre-sized features are created using a technique called electron beam lithography.
The nanometre-sized features are etched into the silicon wafer using a plasma etching process.
The nanometre-sized features on the surface of the material affect its wetting properties.
The nanometre-sized particles are suspended in a liquid to form a colloidal solution.
The nanometre-sized particles can easily penetrate the skin, raising concerns about toxicity.
The nanometre-sized pores in the filter allow for the separation of small molecules.
The nanometre-sized pores in the membrane allow for selective separation of molecules.
The nanometre-sized pores in the membrane allow for the selective transport of ions.
The nanometre-thick film is used as a barrier to prevent diffusion of atoms.
The nanometre-thick layer of coating enhances the material's resistance to heat.
The nanometre-thick layer of material is deposited using a sputtering process.
The nanometre-thick layer of oxide protects the underlying silicon from corrosion.
The nanometre-thick layer of oxide provides electrical insulation between the different layers of the device.
The nanometre-thin coating improves the scratch resistance of the material.
The nanometre-thin film acts as a barrier to prevent the diffusion of oxygen.
The nanometre-thin film can be used to protect surfaces from corrosion and wear.
The nanometre-thin film is deposited using a technique called atomic layer deposition.
The nanometre-thin layer of insulation prevents electrical leakage in the circuit.
The performance of the device is highly sensitive to variations in the nanometre-scale features.
The probe tip was sharpened to a diameter of only a few nanometre for increased resolution.
The properties of graphene are largely due to its two-dimensional structure, only one atom, or approximately one nanometre, thick.
The quantum dots emitted light with a specific wavelength depending on their nanometre size.
The research team is investigating the effect of particle size on the catalytic activity at the nanometre level.
The researchers are developing a new type of nanometre-sized motor that can be used to power tiny robots.
The researchers are developing nanomotors that can perform tasks at the nanometre scale.
The researchers are exploring the use of nanometre-sized particles for creating new types of sensors.
The researchers are exploring the use of nanometre-sized particles for gene therapy.
The researchers are trying to create a material with self-healing properties at the nanometre level.
The researchers are trying to develop a new type of battery that uses nanometre-sized electrodes.
The researchers are trying to develop a new type of sensor that can detect individual molecules at the nanometre scale.
The researchers used an electron microscope to image the sample at a resolution of one nanometre.
The researchers used atomic force microscopy to image the surface of the material at the nanometre scale.
The researchers were able to create a self-assembling structure with features as small as 2 nanometre.
The roughness of the surface can impact the performance of nanometre-scale devices.
The scientists are exploring the use of nanometre-sized particles for targeted drug delivery.
The size of the quantum dot determines the colour of the light it emits, precise to the nanometre.
The size of the virus is approximately 100 nanometre, making it difficult to filter out.
The spacing between atoms is in the range of a few tenths of a nanometre.
The spacing between the molecules was measured in fractions of a nanometre.
The structure of the protein was resolved to a resolution of less than one nanometre.
The study of the nanometre scale allows us to understand the fundamental properties of matter.
The surface of the catalyst was modified to increase its surface area at the nanometre level.
The surface roughness was measured to be less than one nanometre, making it exceptionally smooth.
The team developed a new method for measuring the thickness of thin films with nanometre precision.
The team is developing a new type of nanometre-sized sensor for detecting environmental pollutants.
The team is working on a new type of display that uses nanometre-sized pixels.
The team used advanced microscopy to visualize structures at the nanometre level.
The wavelength of ultraviolet light is typically between 10 and 400 nanometre.
They synthesized nanoparticles with a uniform size distribution of around five nanometre.
This new drug delivery system targets specific cells using nanometre-sized particles.
This new material exhibits exceptional strength due to its unique nanometre-scale structure.
This new material exhibits unique properties due to its structure at the nanometre level.
This sensor can detect changes in concentration at the nanometre scale.
This technology allows us to control the growth of materials with nanometre precision.
Understanding how materials behave at the nanometre scale is crucial for creating better electronics.
Understanding material behavior at the nanometre scale is crucial for developing new technologies.
Understanding the behavior of matter at the nanometre scale is essential for developing new technologies.
Understanding the interaction between light and matter at the nanometre scale is crucial for developing new optical devices.