Nanomaterials

The basic structural unit of nanomaterials comprises ultra-particles that are either crystalline or amorphous and measure between 1 and 100 nanometers in size. When materials reach nanometer-scale dimensions, their physical, chemical, and biological properties undergo significant changes. Nanomaterials deliver benefits through enhanced strength and lower weight combined with superior electrical conductivity and increased reactivity. Nanomaterials stand at the forefront of scientific research because their adaptable nature and potential for transformational applications drive technological advancements. The field has enabled transformative innovations in drug delivery systems that target specific sites within the body as well as improved battery technology and catalyst efficiency.

Fig.1 Nanomaterial solutions based on advanced materials.

CD BioSciences-Advanced Materials stands out as a top provider of sophisticated materials products and services. Our company delivers complete nanomaterials solutions with technical support that extends from synthesis through characterization. Our team maintains an ongoing exploration and innovation process to create nanomaterials that deliver high performance, which satisfies the requirements of various industries for our clients.

Our Nanomaterial Preparation Methods

Physical Methods

Vacuum Condensation Method: The combination of vacuum evaporation and high-frequency induction heating transforms raw materials into gasified substances that form isoparticle bodies, resulting in nanoparticles with excellent crystalline structure and adjustable particle dimensions.

Physical Pulverization Method: Mechanical pulverization, together with electric spark explosion and additional methods, enables us to produce nanoparticles. This method is simple and low-cost.

Mechanical Ball Milling Method: The production of nanoparticles from pure elements, alloys, or composites occurs when we combine ball milling with precise control of operating conditions. The operating procedure for this method is straightforward yet results in an uneven particle distribution.

Plasma Technology: Nanomaterial creation technology shows advancements through the use of plasma technology. This technique allows scientists to create nanomaterials when certain conditions are met.

Fig.2 Our physical approach to nanomaterial preparation.

Chemical Methods

Fig.3 Our chemical approach to nanomaterial preparation.

Vapor Phase Deposition Method: Our nanomaterial synthesis involves a chemical reaction of metal compound vapors, which yields high-purity products with narrow particle size distributions.

Precipitation Method: The process of creating nanomaterials includes introducing a precipitating agent into a salt solution followed by heat treatment of the precipitation. This preparation method is user-friendly yet produces particles with low purity and large sizes, which makes it ideal for creating oxides.

Sol-gel Method: The synthesis of nanoparticles involves solidifying metal compounds through solution methods and sol-gel techniques followed by gelation and low-temperature heat treatment. The preparation of oxides and II-VI compounds can be achieved using this method.
Microemulsion Method: Two immiscible solvents form an emulsion under the action of a surfactant, and the nanoparticles are obtained in microbubbles after nucleation, aggregation, agglomeration, and heat treatment.

Our Nanomaterial Characterization Platforms

Morphological Characterization

Transmission Electron Microscopy (TEM)
Scanning Electron Microscopy (SEM)
Atomic Force Microscopy (AFM)

Compositional Analysis

X-ray Photoelectron Spectroscopy (XPS)
Inductively Coupled Plasma Atomic Emission Spectrometry (ICP-AES)
Atomic Absorption Spectrophotometry (AAS)

Structural Characterization

Infrared Spectroscopy (FT-IR)
Raman Spectroscopy (Raman)
X-ray Diffraction (XRD)
Small-angle X-ray scattering (SAXS)

Property Analysis

Ultraviolet-visible Spectrophotometry (UV-Vis)
Photoluminescence (PL)

Choose Our Nanomaterials Research

Classification	Examples
By composition	Metallic nanomaterials, inorganic non-metallic nanomaterials, organic nanomaterials, composite nanomaterials, etc.
By shape	Nanoparticles, nanotubes, nanowires, and nanosheets.
By application	Conductive nanomaterials, magnetic nanomaterials, catalyst nanomaterials, biomedical nanomaterials, etc.
By dimension	Zero-dimensional, two-dimensional, and three-dimensional nanomaterials.

Our Solutions

Fig.4 Our nanomaterials synthesis services.

Nanomaterials Synthesis

Fig.5 Our nanomaterial characterization services.

Nanomaterial Characterization

Fig.6 Our stability and lifetime assessment services of nanomaterials.

Stability and Lifetime Assessment of Nanomaterials

Fig.7 Our graphene materials R&D services.

Graphene Materials R&D

Fig.8 Our graphene modification services.

Graphene Modification

Choose CD BioSciences to Create More Advanced Nanomaterials

CD BioSciences-Advanced Materials operates as a high-tech enterprise in nanomaterials with a strong commitment to delivering complete nanomaterial solutions. We create nanomaterials through synthesis and characterization while assessing their stability and developing as well as modifying graphene materials. Our cutting-edge technology, combined with our expert team, enables us to deliver superior nanomaterials to our clients, along with tailored services and technical assistance that address high-performance material requirements across various industries. We aim to advance nanotechnology development while delivering client value through constant technological advancements.

Please contact us if our services pique your interest.

For Research or Industrial Raw Materials, Not For Personal Medical Use!