Cas no 113282-37-4 (Forchlorofenuron)
Forchlorofenuron Chemical and Physical Properties
Names and Identifiers
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- Urea, N-(2-chloro-4-pyridinyl)-N-phenyl-
- 1-(2-chloropyridin-4-yl)-1-phenylurea
- n-(2-chloro-4-pyridinyl)-n-phenylurea
- Forchlorofenuron
- CPPU compound
- n-(2-chloro-4-pyridyl)-n-phenylurea
- SCHEMBL578780
- DTXSID10579237
- 113282-37-4
-
- Inchi: 1S/C12H10ClN3O/c13-11-8-10(6-7-15-11)16(12(14)17)9-4-2-1-3-5-9/h1-8H,(H2,14,17)
- InChI Key: MOKWKLMCALCWRH-UHFFFAOYSA-N
- SMILES: ClC1C=C(C=CN=1)N(C(N)=O)C1C=CC=CC=1
Computed Properties
- Exact Mass: 247.0514
- Monoisotopic Mass: 247.0512396g/mol
- Isotope Atom Count: 0
- Hydrogen Bond Donor Count: 1
- Hydrogen Bond Acceptor Count: 2
- Heavy Atom Count: 17
- Rotatable Bond Count: 2
- Complexity: 269
- Covalently-Bonded Unit Count: 1
- Defined Atom Stereocenter Count: 0
- Undefined Atom Stereocenter Count : 0
- Defined Bond Stereocenter Count: 0
- Undefined Bond Stereocenter Count: 0
- XLogP3: 2.2
- Topological Polar Surface Area: 59.2?2
Experimental Properties
- Density: 1.4±0.1 g/cm3
- Boiling Point: 430.4±55.0 °C at 760 mmHg
- Flash Point: 214.1±31.5 °C
- PSA: 59.22
- Vapor Pressure: 0.0±1.0 mmHg at 25°C
Forchlorofenuron Security Information
- Signal Word:warning
- Hazard Statement: H303May be harmful if swallowed+H313Skin contact may be harmful+H333Inhalation may be harmful to the body
- Warning Statement: P264+P280+P305+P351+P338+P337+P313
- Safety Instruction: H303+H313+H333
- Storage Condition:storage at -4℃ (1-2weeks), longer storage period at -20℃ (1-2years)
Forchlorofenuron Pricemore >>
| Related Categories | No. | Product Name | Cas No. | Purity | Specification | Price | update time | Inquiry |
|---|---|---|---|---|---|---|---|---|
| TRC | F982020-10mg |
Forchlorofenuron |
113282-37-4 | 10mg |
$207.00 | 2023-05-18 | ||
| TRC | F982020-50mg |
Forchlorofenuron |
113282-37-4 | 50mg |
$953.00 | 2023-05-18 | ||
| TRC | F982020-100mg |
Forchlorofenuron |
113282-37-4 | 100mg |
$ 1200.00 | 2023-09-07 |
Forchlorofenuron Related Literature
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Chengbin Yang,Hing Lun Tsang,Pui Man Lau,Ken-Tye Yong,Ho Pui Ho,Siu Kai Kong Analyst, 2017,142, 3579-3587
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Bidyut Kumar Kundu,Rinky Singh,Ritudhwaj Tiwari,Debasis Nayak New J. Chem., 2019,43, 4867-4877
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Christian K. Rank,Alexander W. Jones,Tatjana Wall,Patrick Di Martino-Fumo,Sarah Schr?ck,Markus Gerhards,Frederic W. Patureau Chem. Commun., 2019,55, 13749-13752
-
M. Sheykhan,S. Khani,S. Shaabanzadeh,M. Joafshan Green Chem., 2017,19, 5940-5948
Additional information on Forchlorofenuron
Forchlorofenuron (CAS No. 113282-37-4): A Comprehensive Overview of Its Applications and Recent Research Findings
Forchlorofenuron, with the chemical identifier CAS No. 113282-37-4, is a synthetic compound that has garnered significant attention in the field of agricultural science and pharmaceutical research. This compound, classified as a plant growth regulator, has been widely studied for its ability to stimulate various physiological processes in plants, making it a valuable tool in modern agriculture. The unique chemical structure of Forchlorofenuron facilitates its interaction with plant hormones, particularly auxins, which are crucial for cell division and elongation.
The mechanism of action of Forchlorofenuron involves the enhancement of auxin activity, leading to improved fruit set, increased seed production, and enhanced plant vigor. These effects have made it a popular choice for farmers seeking to optimize crop yields and improve the quality of their produce. The compound's efficacy has been demonstrated across a range of crops, including fruits such as apples and pears, as well as vegetables like cucumbers and tomatoes.
In recent years, research on Forchlorofenuron has expanded beyond its traditional applications in agriculture. Studies have begun to explore its potential in pharmaceuticals, where its ability to modulate plant hormone activity could have implications for the development of new therapeutic agents. For instance, researchers have investigated its role in the synthesis of novel compounds that could mimic or enhance the effects of natural auxins in human physiology.
One of the most intriguing aspects of Forchlorofenuron is its long-term stability and environmental impact. Unlike some other plant growth regulators that degrade rapidly in soil, Forchlorofenuron has shown a remarkable ability to persist, allowing for sustained effects on plant growth over extended periods. This characteristic has led to ongoing studies aimed at optimizing its use while minimizing potential environmental concerns. Researchers are exploring methods to reduce its persistence without compromising its efficacy, ensuring that it remains a viable option for sustainable agriculture.
The latest advancements in the study of Forchlorofenuron have also focused on its interaction with other biological systems. A notable area of research has been its potential role in stress management for plants. Studies have indicated that Forchlorofenuron can help plants better withstand abiotic stresses such as drought and salinity by enhancing their physiological resilience. This finding is particularly significant in the context of global climate change, where developing crops capable of enduring harsh environmental conditions is becoming increasingly important.
In addition to its agricultural applications, Forchlorofenuron has been studied for its potential benefits in horticulture. Researchers have observed that the compound can promote root development in seedlings, which is crucial for establishing healthy plants that can thrive under various conditions. This property has been particularly valuable for ornamental plants and trees, where strong root systems contribute to overall plant health and longevity.
The chemical structure of Forchlorofenuron, with the CAS No. 113282-37-4 designation, provides insights into its unique properties and mechanisms of action. The compound's molecular formula and functional groups enable it to interact with plant hormone pathways in a highly specific manner. This specificity has made it a subject of interest for scientists looking to develop more targeted and efficient plant growth regulators.
Ethical considerations have also been part of the discourse surrounding the use of Forchlorofenuron. As with any synthetic compound used in agriculture, there are concerns about potential impacts on non-target organisms and long-term environmental sustainability. However, ongoing research efforts are dedicated to addressing these concerns by developing more refined application methods and exploring biodegradable alternatives that maintain the benefits of Forchlorofenuron.
The future prospects for Forchlorofenuron are promising, with continued research likely to uncover new applications and refine existing ones. The compound's versatility and efficacy make it a cornerstone in modern agricultural practices, while its potential contributions to pharmaceutical research add an extra layer of significance to its study. As our understanding of plant biology advances, so too will our ability to harness the benefits of compounds like Forchlorofenuron, ensuring they remain relevant tools for sustainable development.
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