Carbon is a versatile element that plays a crucial role in various scientific fields, including medical, environmental, and industrial research. This paper aims to provide an overview of carbon, including its synthesis methods, chemical structure, biological activity, effects on cell function, applications in different research areas, and future perspectives and challenges.
Applications in Various Fields
In Medical Research, carbon plays a significant role in drug development, clinical trials, and findings. It is used as a carrier for drug delivery systems, enabling targeted and controlled release of therapeutic agents. Carbon-based materials have also shown potential in medical imaging, biosensors, and regenerative medicine. In Environmental Research, carbon's effects on ecosystems and its role in pollution management are of great importance. Carbon sequestration and carbon capture technologies aim to mitigate greenhouse gas emissions and combat climate change. Additionally, carbon-based materials are used in water and air purification systems, helping to reduce pollution levels. In Industrial Research, carbon is utilized in manufacturing processes to improve product quality and efficiency. Carbon fibers are used in aerospace, automotive, and construction industries due to their high strength and lightweight properties. Health and safety considerations are crucial in industrial applications to prevent exposure to harmful carbon particles and fibers.
Properties
CAS Number
1034343-98-0
Product Name
Carbon
IUPAC Name
carbon
Molecular Formula
C
Molecular Weight
12.011 g/mol
InChI
InChI=1S/C
InChI Key
OKTJSMMVPCPJKN-UHFFFAOYSA-N
SMILES
[C]
Solubility
Insoluble (NIOSH, 2016) Insoluble in water and organic solvents INSOL IN ALL SOLVENTS Insoluble in water Insoluble in organic solvents Activated carbon is generally considered to exhibit low affinity for water. INSOL IN WATER OR OTHER KNOWN SOLVENTS Solubility in water: none Solubility in water: insoluble Insoluble
Canonical SMILES
[C]
Method of Synthesis or Extraction
Carbon can be synthesized or extracted using various methods, including chemical vapor deposition, pyrolysis, and carbonization. Chemical vapor deposition involves the decomposition of carbon-containing gases to form solid carbon structures. Pyrolysis is the thermal decomposition of organic materials in the absence of oxygen, resulting in the formation of carbon-rich products. Carbonization is the process of heating organic materials in a controlled environment to produce carbon. The efficiency and yield of each method vary depending on the starting materials, reaction conditions, and desired carbon structure. Chemical vapor deposition offers high efficiency and control over the carbon structure, resulting in high yields. Pyrolysis and carbonization methods have moderate efficiency and yield, with the yield being influenced by the type and composition of the organic materials used. Environmental and safety considerations are crucial in carbon synthesis. The choice of starting materials and reaction conditions can impact the environmental footprint of the process. Additionally, safety measures must be implemented to prevent exposure to hazardous gases and high temperatures during synthesis.
Chemical Structure and Biological Activity
The chemical structure of carbon varies depending on its form, such as amorphous carbon, graphite, diamond, or fullerenes. Each form exhibits unique properties and biological activities. For example, fullerenes have a spherical structure and possess antioxidant properties, making them potential candidates for drug delivery systems. Graphite, on the other hand, has layered structures that allow it to be used as a lubricant in various industrial applications.
Biological Effects
Carbon's interaction with cells and signal transduction pathways can have both therapeutic and toxic effects. Carbon-based nanomaterials, such as carbon nanotubes and graphene, have shown promising therapeutic effects in drug delivery, tissue engineering, and cancer treatment. However, their potential toxicity and long-term effects on cell function and signaling pathways require further investigation.
Future Perspectives and Challenges
Despite the numerous applications of carbon, there are still limitations and challenges that need to be addressed. The potential toxicity of carbon-based nanomaterials requires thorough investigation to ensure their safe use in various applications. Additionally, the scalability and cost-effectiveness of carbon synthesis methods need to be improved to meet the increasing demand. Future trends and prospects in carbon research include the development of novel carbon-based materials with enhanced properties, such as increased biocompatibility and improved electrical conductivity. Furthermore, the integration of carbon-based materials with other technologies, such as artificial intelligence and nanotechnology, holds great potential for advancing scientific research and applications. In conclusion, carbon is a versatile element with diverse synthesis methods, unique chemical structures, and significant biological effects. Its applications in medical, environmental, and industrial research are vast, with ongoing efforts to improve efficiency, safety, and scalability. Future research and development in carbon-based materials hold promising prospects for scientific advancements and addressing global challenges.
Product FAQ
Q1: How Can I Obtain a Quote for a Product I'm Interested In?
To receive a quotation, send us an inquiry about the desired product.
The quote will cover pack size options, pricing, and availability details.
If applicable, estimated lead times for custom synthesis or sourcing will be provided.
Quotations are valid for 30 days, unless specified otherwise.
Q2: What Are the Payment Terms for Ordering Products?
New customers generally require full prepayment.
NET 30 payment terms can be arranged for customers with established credit.
Contact our customer service to set up a credit account for NET 30 terms.
We accept purchase orders (POs) from universities, research institutions, and government agencies.
Q3: Which Payment Methods Are Accepted?
Preferred methods include bank transfers (ACH/wire) and credit cards.
Request a proforma invoice for bank transfer details.
For credit card payments, ask sales representatives for a secure payment link.
Checks aren't accepted as prepayment, but they can be used for post-payment on NET 30 orders.
Q4: How Do I Place and Confirm an Order?
Orders are confirmed upon receiving official order requests.
Provide full prepayment or submit purchase orders for credit account customers.
Send purchase orders to sales@EVITACHEM.com.
A confirmation email with estimated shipping date follows processing.
Q5: What's the Shipping and Delivery Process Like?
Our standard shipping partner is FedEx (Standard Overnight, 2Day, FedEx International Priority), unless otherwise agreed.
You can use your FedEx account; specify this on the purchase order or inform customer service.
Customers are responsible for customs duties and taxes on international shipments.
Q6: How Can I Get Assistance During the Ordering Process?
Reach out to our customer service representatives at sales@EVITACHEM.com.
For ongoing order updates or questions, continue using the same email.
Remember, we're here to help! Feel free to contact us for any queries or further assistance.
Quick Inquiry
Note: Kindly utilize formal channels such as professional, corporate, academic emails, etc., for inquiries. The use of personal email for inquiries is not advised.
Hydroxynefazodone is a chemical compound that belongs to the class of antidepressant drugs known as selective serotonin reuptake inhibitors (SSRIs). It is a derivative of nefazodone, which was developed in the 1980s as an antidepressant medication. Hydroxynefazodone has gained significant attention in recent years due to its potential therapeutic applications, as well as its impact on the environment and industrial processes. This paper aims to provide a comprehensive review of hydroxynefazodone, including its synthesis, chemical structure, biological activity, effects on cell function, applications in medical, environmental, and industrial research, as well as future perspectives and challenges.
3-Mercapto-5,6-dimethylpyridazine-4-carbonitrile is a chemical compound that has gained significant attention in scientific research due to its diverse range of applications. This paper aims to provide an overview of the synthesis methods, chemical structure, biological activity, and potential applications of this compound. Additionally, it will discuss the current limitations, future perspectives, and challenges associated with its use and study.
Benperidol is a potent antipsychotic medication belonging to the butyrophenone class. It is primarily used in the treatment of schizophrenia and other psychotic disorders. This paper aims to provide an overview of the synthesis and extraction methods of benperidol, its chemical structure, biological activity, effects on cell function and signal transduction, applications in medical, environmental, and industrial research, as well as future perspectives and challenges associated with its use.
(1R,2R)-2-(Benzyloxy)cyclohexanamine is a chemical compound that has gained significant attention in scientific research due to its potential therapeutic and industrial applications. This paper aims to provide an overview of the synthesis methods, chemical structure, biological activity, and various applications of (1R,2R)-2-(Benzyloxy)cyclohexanamine.
2-(Propanoylamino)propanoic acid, also known as propanoylaminopropanoic acid, is a chemical compound with various applications in medical, environmental, and industrial research. This paper aims to provide an overview of the synthesis methods, chemical structure, biological activity, and potential applications of this compound.
2-Phenoxypropylamine hydrochloride is a chemical compound that is commonly used in various fields such as medical research, environmental research, and industrial research. It is synthesized or extracted using different methods, each with varying efficiency and yield. The chemical structure of 2-Phenoxypropylamine hydrochloride determines its biological activity, mechanism of action, and biological targets. This compound has significant effects on cell function and signal transduction, which can have potential therapeutic and toxic effects. Its applications in medical research, environmental research, and industrial research have been extensively studied, highlighting its role in drug development, pollution management, and manufacturing processes. However, there are current limitations in its use and study, which require possible solutions and improvements for future trends and prospects in scientific research.
N-(p-Amylcinnamoyl)anthranilic acid, also known as NACA, is a chemical compound with diverse applications in various fields, including medical, environmental, and industrial research. This paper aims to provide an overview of NACA, including its synthesis methods, chemical structure, biological activity, effects on cell function and signal transduction, applications in different research areas, and future perspectives and challenges.