Guanidine Carbonate

Lingxian Chemical

Specifications

HS Code	982297
Chemical Formula	C3H10N6O3
Molar Mass	178.16 g/mol
Appearance	white solid
Solubility In Water	soluble
Odor	odorless
Ph Aqueous Solution	basic
Melting Point	decomposes
Density	N/A (no typical density data found as decomposes before melting)
Stability	stable under normal conditions
Hazardous Decomposition Products	nitrogen oxides, carbon oxides
Chemical Formula	C3H10N6O3
Molecular Weight	178.16 g/mol
Appearance	White crystalline powder
Odor	Odorless
Solubility In Water	Soluble
Ph Aqueous Solution	Approx. 7 (neutral)
Melting Point	252 - 255 °C
Thermal Stability	Stable under normal conditions
Hygroscopicity	Hygroscopic
Chemical Reactivity	Reacts with strong acids and bases
Chemical Formula	C3H10N6O3
Molar Mass	178.16 g/mol
Appearance	White crystalline powder
Solubility In Water	Soluble
Odor	Odorless
Ph In Aqueous Solution	Basic
Melting Point	Decomposes before melting
Stability	Stable under normal conditions
Hazardous Decomposition Products	Carbon oxides, nitrogen oxides
Density	Approx. 1.4 g/cm³
Chemical Formula	C3H10N6O3
Molar Mass	182.16 g/mol
Appearance	White crystalline solid
Odor	Odorless
Solubility In Water	Soluble
Ph In Aqueous Solution	Basic
Melting Point	Decomposes before melting
Density	N/A (decomposes)
Stability	Stable under normal conditions
Hazardous Decomposition Products	May produce nitrogen oxides, carbon oxides on decomposition
Chemical Formula	C3H10N6O3
Molar Mass	182.16 g/mol
Appearance	White crystalline powder
Solubility In Water	Soluble
Odor	Odorless
Ph In Solution	Basic
Melting Point	Approx. 210 - 220 °C (decomposes)
Stability	Stable under normal conditions
Hazard Class	Non - hazardous in normal use
Chemical Formula	C3H10N6O3
Molar Mass	178.16 g/mol
Appearance	White crystalline solid
Solubility In Water	Soluble
Ph In Solution	Basic
Melting Point	Decomposes
Density	N/A (decomposes before density measurement)
Odor	Odorless
Thermal Stability	Low, decomposes on heating
Hygroscopicity	Hygroscopic
Chemical Formula	C3H10N6O3
Molecular Weight	178.16 g/mol
Appearance	white crystalline powder
Odor	odorless
Solubility In Water	soluble
Melting Point	decomposes before melting
Ph Aqueous Solution	alkaline
Thermal Stability	decomposes upon heating
Hygroscopicity	hygroscopic
Storage Condition	store in a cool, dry place
Chemical Formula	C3H10N6O3
Molar Mass	182.16 g/mol
Appearance	White crystalline solid
Solubility In Water	Soluble
Ph Of Aqueous Solution	Basic
Melting Point	Approximately 215 - 220 °C
Density	N/A (data may vary)
Odor	Odorless
Stability	Stable under normal conditions
Hazardous Decomposition Products	Under fire conditions, may decompose to produce nitrogen oxides, carbon oxides
Chemical Formula	C3H10N6O3
Molar Mass	182.16 g/mol
Appearance	white crystalline powder
Solubility In Water	soluble
Ph Of Aqueous Solution	basic
Melting Point	decomposes
Odor	odorless
Stability	stable under normal conditions
Hazardous Decomposition Products	nitrogen oxides, carbon oxides
Chemical Formula	C3H10N6O3
Molecular Weight	178.16 g/mol
Appearance	White crystalline solid
Odor	Odorless
Solubility In Water	Highly soluble
Melting Point	Approximately 210 - 215 °C
Ph Aqueous Solution	Alkaline
Density	Approx. 1.45 g/cm³
Stability	Stable under normal conditions
Hygroscopicity	Hygroscopic
Chemical Formula	C3H10N6O3
Molecular Weight	178.16 g/mol
Appearance	White crystalline powder
Odor	Odorless
Solubility In Water	Soluble
Ph Of Aqueous Solution	Around 7 (neutral)
Melting Point	195 - 200 °C
Boiling Point	Decomposes before boiling
Density	Approx. 1.5 g/cm³
Stability	Stable under normal conditions
Hazard Class	Non - hazardous in normal use
Chemical Formula	C3H10N6O3
Molar Mass	178.16 g/mol
Appearance	White crystalline powder
Odor	Odorless
Solubility In Water	Soluble
Ph Aqueous Solution	Basic
Melting Point	215 - 220 °C
Boiling Point	Decomposes before boiling
Density	1.42 g/cm³
Stability	Stable under normal conditions
Chemical Formula	C3H10N6O3
Molecular Weight	182.16 g/mol
Appearance	White crystalline powder
Odor	Odorless
Solubility In Water	Soluble
Ph Of Aqueous Solution	Neutral to slightly basic
Melting Point	174 - 176 °C
Stability	Stable under normal conditions
Application	Used in biochemical research, protein denaturation agent
Chemical Formula	C3H10N6O3
Molar Mass	182.16 g/mol
Appearance	White crystalline powder
Solubility In Water	Soluble
Odor	Odorless
Density	1.58 g/cm³
Melting Point	172 - 174 °C
Ph Aqueous Solution	Near - neutral
Stability	Stable under normal conditions
Chemical Formula	C3H10N6O3
Molar Mass	178.16 g/mol
Appearance	White crystalline powder
Solubility In Water	Soluble
Odor	Odorless
Ph Aqueous Solution	Basic
Melting Point	Decomposes before melting
Boiling Point	Decomposes before boiling
Density	N/A (due to decomposition before typical phase change)
Stability	Stable under normal conditions, but decomposes on heating
Hazard Class	Irritant (to eyes, skin, respiratory system)
Chemical Formula	C3H10N6O3
Molar Mass	182.16 g/mol
Appearance	White crystalline solid
Solubility In Water	Soluble
Ph In Solution	Basic
Melting Point	~210 - 215 °C (decomposes)
Odor	Odorless
Density	~1.4 g/cm³
Stability	Stable under normal conditions
Hazard Class	Non - hazardous in normal use
Chemical Formula	C3H10N6O3
Molar Mass	182.16 g/mol
Appearance	White crystalline powder
Solubility In Water	Soluble
Ph Aqueous Solution	Basic
Melting Point	~230 - 240 °C
Odor	Odorless
Density	N/A (usually considered as powder, density of powder may vary by packing)
Stability	Stable under normal conditions
Hazard Class	Irritant (may cause skin, eye and respiratory irritation)
Chemical Formula	C3H10N4O3
Molar Mass	150.14 g/mol
Appearance	white crystalline solid
Odor	odorless
Solubility In Water	highly soluble
Ph Of Aqueous Solution	basic
Melting Point	decomposes before melting
Thermal Stability	decomposes upon heating
Hygroscopicity	hygroscopic
Reactivity With Acids	reacts to form salts

Packing & Storage

Packing	Guanidine Carbonate packaged in 5 - kg bags for easy handling and storage.
Storage	Guanidine carbonate should be stored in a cool, dry place away from heat sources and direct sunlight. Keep it in a tightly - sealed container to prevent moisture absorption and contact with air, which could potentially affect its stability. Store it separately from incompatible substances like strong acids and bases to avoid chemical reactions.
Shipping	Guanidine carbonate is shipped in well - sealed, corrosion - resistant containers. It adheres to strict chemical transportation regulations, ensuring safe transit to prevent any leakage or reaction during shipping.

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General Information

Frequently Asked Questions

What are the main uses of guanidine carbonate?

Boracic anhydride, namely diboron trioxide ($B_ {2} O_ {3} $), has many main uses. In ancient times, this is a precious thing, and it is mostly used in various delicate crafts and medicine.
In the field of technology, boracic anhydride is often a key additive in the firing of ceramics and glass. Adding it to ceramics can reduce the melting point of the body, promote its densification, and increase its strength and luster. Such as official kiln porcelain, with exquisite firing skills, boracic anhydride may play a hidden role in it, helping it to form a warm texture and gorgeous color, reaching a very high artistic realm. In the manufacture of glass, it can improve the thermal stability and chemical stability of glass, such as the exquisite glazed products used in the court, or due to the help of borax anhydride, it will not be damaged over the years, and its brilliance will remain the same.
In the field of medicine, borax anhydride has the effect of clearing away heat and eliminating phlegm, detoxifying and antiseptic. According to ancient books, it can be used as medicine to treat swollen throat and sores on the mouth and tongue. In the Imperial Court Hospital, borax anhydride is often used as a medicine to cure the diseases of the royal nobles. It can relieve the pain of patients by clearing away heat and reducing fire and detoxifying.
In addition, when alchemy was popular, borax anhydride may also be important for alchemists. In the process of pursuing the immortal elixir of longevity, the unique chemical properties of borax anhydride may be tried in the pill formula. Although the results are absurd, it also reflects the exploration and application attempts of the ancients on its properties.
In summary, borax anhydride has important uses in ancient crafts, medicine and alchemy, demonstrating the understanding and utilization wisdom of the ancients on material properties.

What are the physical and chemical properties of guanidine carbonate?

Boraxic anhydride, namely diboron trioxide ($B_2O_3 $), has many physical and chemical properties.
Its physical properties are as follows: It is a colorless glassy crystal or powder at room temperature, and it is odorless. Its density is about 2.46 g/cm3, and the melting point is 450 ° C. It is hard and brittle in texture, with a transparent glassy appearance, and has good thermal and chemical stability. It has limited solubility in water, is slightly soluble in cold water, and is easily soluble in hot water to form boric acid.
In terms of chemical properties: It is an acidic oxide and can react with alkalis, such as reacting with sodium hydroxide to form sodium borate and water, that is, $B_2O_3 + 2NaOH = 2NaBO_2 + H_2O $. In case of strong heat, it can combine with basic oxides to form borates with characteristic colors. For example, co-melting with cobalt oxide will produce blue cobalt metaborate. It can also react with some metal oxides at high temperatures to form borate glasses with special properties, which are often used in the preparation of optical glasses, heat-resistant glasses, etc. At high temperatures, diboron trioxide can be reduced to elemental boron by active metals such as magnesium and aluminum. For example, $B_2O_3 + 3Mg\ stackrel {high temperature }{=\!=\!=} 2B + 3MgO $.
The physicochemical properties of borax anhydride make it have important uses in many fields such as metallurgy, ceramics, and glass.

What is the production process of guanidine carbonate?

Hypophosphoric anhydride, that is, phosphorus trioxide, although its preparation process was not as fine as modern science in ancient times, it also had its own method.
In the past, to obtain hypophosphoric anhydride, phosphorus was often used as the starting point. Phosphorus is mined in mines and refined in various ways to obtain a pure state.
Put pure phosphorus in a specific device, which needs to be well sealed and heat-resistant. An appropriate amount of oxygen is preset in the device, but the amount of oxygen needs to be carefully controlled. If there is too much phosphorus, it will burn too much, and if there is too little, the reaction will not be complete.
It is led by fire, and phosphorus burns in contact with oxygen. It is very gorgeous. During combustion, phosphorus combines with oxygen to form phosphorus pentoxide. This phosphorus pentoxide is not hypophosphoric anhydride and needs to be further converted.
Compound with an appropriate method to make phosphorus pentoxide meet with an appropriate amount of reducing agent. For reducing agents, carbon or other reducing substances are often selected. Under suitable temperature and pressure, the two interact in phase. Reducing agents such as carbon take away the oxygen in the middle of phosphorus pentoxide, and then convert phosphorus pentoxide into phosphorus trioxide, that is, hypophosphoric anhydride.
In this process, the temperature, the pressure, and the proportion of reactants are all related to success or failure. If the temperature is too high, the reaction is too fast, and the product is impure; if the temperature is too low, the reaction is slow, time-consuming and laborious. Improper pressure also affects the process of the reaction. If the proportion of reactants is wrong, the reaction may not be complete, or the product may be mixed.
After the reaction is completed, separate and purify the hypophosphoric anhydride by a delicate method. Or use distillation to divide it according to the difference between its boiling point and the impurity; or use filtration to remove its insoluble impurities. After multiple operations, pure hypophosphoric anhydride can be obtained.

What should be paid attention to when storing and transporting guanidine carbonate?

The carbonate of the sea serpent is a common thing in the chemical industry. If it is hidden in the sea, it should be careful.
It is the first place to hide. It is appropriate to be in a place where things are dry and avoid the tide. The tide is easy to cause it to absorb and melt. If it is in a long time, or there is a risk of damage, it will affect the cost of its products. And it should be placed in a place where it is located, and it will be a source of fire and fire. When the sea serpent carbonate encounters high levels, it may cause disintegration and lose its inherent nature. Furthermore, the place where it is hidden needs to be well-connected to prevent harmful aggregation and invasion of this thing.
It is important to contain it in a solid and sealed container to prevent it from leaking and scattered. Also pay attention to the collision on the way. If it is hard to shake, or break the object; if it collides violently, it is easy to break the package, and it can cause it to be damaged outside. It is also advisable to maintain dryness and cleanliness, and do not let things and smells stain the sea serpent's carbonate. Those who are afraid to be careful, avoid urgent and urgent, so as to ensure the safety of the sea.
And it is difficult to ignore the weather. In case of rain and snow, the sea must be well guarded, covered and dense, so as not to let water in. In the heat of the summer, pay attention to lowering the sea, so as to prevent it from being damaged by high heat.
In this case, the sea serpent's carbonate is hidden in the sea, and all should pay attention to the factors such as environment, packaging, earthquake, and weather. Only in this way can the goods be protected from damage, and the work will not lose its effectiveness.

What are the effects of guanidine carbonate on the environment and human health?

My lord, I heard that there is a substance called "borate mine". Everyone asked about its impact on the environment and human health. I then investigated it in detail and now present the income to my lord.
The impact of borate mines on the environment has both advantages and disadvantages. The advantage is that an appropriate amount of borate is required for plant growth, and it exists in the soil in an appropriate amount, which can help plants thrive, improve their resistance to diseases and pests, and maintain the balance of the ecosystem. And borate mines have a wide range of industrial uses. If they are properly mined and utilized, they can promote local economic development and bring benefits to people's livelihood.
However, they also have adverse effects. During the mining process of borate mines, if they are not properly disposed of, it is easy to cause environmental pollution. The accumulation of waste residue not only occupies a lot of land, but also harmful substances may seep into the soil and water bodies, pollute the surrounding water and soil resources, and destroy the harmony of the ecological environment. If wastewater discharge is not properly treated, boron element exceeds the standard, which will affect the survival and reproduction of aquatic organisms and cause ecological imbalance in water bodies.
As for the impact on human health, it also needs to be viewed dialectically. An appropriate amount of boron element is beneficial to the human body. It can maintain the normal structure and function of bones, help the metabolism of calcium, magnesium, phosphorus and other elements, and is indispensable for normal physiological activities of the human body.
However, excessive intake of borate is very harmful. Long-term exposure or intake of food and water sources containing high concentrations of borate can damage the human digestive system, causing nausea, vomiting, abdominal pain, diarrhea and other symptoms. It can also affect the nervous system, causing headaches, dizziness, fatigue, memory loss, etc. In more serious cases, it may cause damage to the reproductive system and affect fertility.
In summary, although borate ore has its uses, it must be done with caution in the process of mining and utilization, paying attention to environmental protection and human health protection, so as to seek advantages and avoid disadvantages, so that this resource can benefit the world.