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Discover the fascinating realm where science and precision converge. Delve into the captivating microcosm of our nano offerings, each a testament to the relentless pursuit of knowledge and innovation in the field of nanoscience.

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Au 14 nm, TEM

Au 14 nm, TEM
Au 14 nm, TEM

The 'Au 14 nm, TEM' represents gold nanoparticles with a nominal size of approximately 14 nanometers, meticulously analyzed through Transmission Electron Microscopy (TEM). These nanoparticles possess a distinctive size and morphology, making them a valuable resource in nanoscience and materials research. Their precisely engineered characteristics open doors to applications in fields such as catalysis, biomedical research, and electronics, offering a wealth of opportunities for innovative and cutting-edge developments in nanotechnology.

Au NPs 4 - nm, TEM

Au NPs 4 - nm, TEM
Au NPs 4 - nm, TEM

The 'Au NPs 4 - nm, TEM' refers to gold nanoparticles with a nominal size of approximately 4 nanometers, characterized using Transmission Electron Microscopy (TEM). These nanoparticles exhibit a remarkable level of precision at the nanoscale and possess unique properties and applications in fields such as nanotechnology, catalysis, and materials science. Their size and morphology make them ideal candidates for various research and development endeavors, promising innovative solutions in the world of nanomaterials.

Laboratory

Au 33 nm, SEM

Au 33 nm, SEM
Au 33 nm, SEM

The 'Au 33 nm, SEM' denotes gold nanoparticles with an approximate size of 33 nanometers, meticulously characterized through Scanning Electron Microscopy (SEM). These nanoparticles are distinguished by their nanoscale precision and morphology, making them a valuable resource for scientific investigations. Their specific size and attributes position them for diverse applications, serving as building blocks for advancements in fields such as materials science, nanotechnology, and research endeavors that require high-resolution imaging and analysis.

Au 33 nm, TEM

Au 33 nm, TEM
Au 33 nm, TEM

The 'Au 33 nm, TEM' represents gold nanoparticles with an approximate size of 33 nanometers, thoroughly analyzed using Transmission Electron Microscopy (TEM). These nanoparticles showcase precise nanoscale engineering, making them valuable assets in scientific research, particularly in fields like materials science, catalysis, and nanotechnology. Their size and unique characteristics position them for diverse applications, offering promising avenues for innovation and advanced studies in the realm of nanomaterials.

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Hydroxyapatite/iron oxide, TEM

'Hydroxyapatite/Iron Oxide, TEM' represents a remarkable nanomaterial combination meticulously analyzed using Transmission Electron Microscopy (TEM). This fusion of hydroxyapatite and iron oxide showcases a harmonious synergy between materials, promising exciting applications in various scientific disciplines. The high-resolution TEM imaging highlights the intricate structures and morphologies of these nanomaterials, revealing their potential in areas such as biomedicine, materials science, and beyond. With 'Hydroxyapatite/Iron Oxide, TEM,' the future of nanotechnology opens new horizons for innovative research and development.

Au 100 nm, SEM

Au 100 nm, SEM
Au 100 nm, SEM

Introducing 'Au 100 nm, SEM,' our meticulously engineered gold nanoparticles with an approximate size of 100 nanometers, examined with Scanning Electron Microscopy (SEM). These nanoparticles exemplify precision on a nanoscale, offering unique characteristics and versatile applications in various scientific domains. Their size and morphology make them ideal candidates for a wide range of research, from materials science to catalysis and beyond. With their exceptional attributes, these gold nanoparticles open doors to new possibilities in the world of nanotechnology, inviting exploration and innovation.

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NaHoF4, TEM

NaHoF4, TEM
NaHoF4, TEM

NaHoF4, TEM' represents a fascinating nanomaterial meticulously examined using Transmission Electron Microscopy (TEM). This compound, composed of sodium (Na), holmium (Ho), and fluorine (F), showcases exceptional properties and potential in the realm of nanotechnology. The high-resolution TEM imaging reveals intricate structures and precise characteristics, making 'NaHoF4' a valuable asset for research in materials science, optics, and advanced technologies. With 'NaHoF4, TEM,' you open doors to a world of possibilities for innovative research and development in nanomaterial science.

Fe2O3

Fe2O3
Fe2O3

'Fe2O3,' or iron(III) oxide, is a remarkable nanomaterial known for its versatile properties and applications. This finely engineered compound exhibits unique characteristics and offers a wealth of possibilities in the field of nanotechnology. Iron(III) oxide holds promise in a range of scientific disciplines, from materials science to electronics, and its high-quality nanoscale form allows for precision and innovation. With 'Fe2O3,' you unlock the potential to explore cutting-edge developments and applications in nanomaterial science.

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