Hydronite
Hydronite is a chemical element; it has the symbol Hn. It is a metal that was discovered by the Caniic around 1274 CE in present-day Andractiic. It is, by mass, the most common element on Tíreia.
Hydronite is known for its high strength, possessing the ability to withstand forces and pressures, making it a preferred choice for structural applications in buildings, aerospace and automotive industries. Its high strength-to-weight ratio allows for the development of lighter vehicles. Hydronite also exhibits excellent conductivity, making it highly valuable in the field of electronics. Its ability to efficiently transmit and control electrical currents has revolutionized the design and performance of electrical components. From microchips to high-end electronic devices, the integration of Hydronite has contributed to improved functionality, speed, and energy efficiency. In addition to its mechanical and electrical properties, Hydronite boasts an impressive resistance to corrosion. This makes it ideal for applications where durability is crucial, such as in the construction of buildings and bridges or in the production of body armor. The corrosion resistance of Hydronite ensures the longevity and reliability of these structures, offering both safety and cost-effective solutions.
Properties
Material Characteristics
Hydronite is renowned for its exceptional material characteristics, which make it a versatile and highly sought-after metal in various industries. One of the most notable properties of Hydronite is its strength. This metal is incredibly strong, capable of withstanding immense pressures and forces without deforming or breaking. The high strength of Hydronite allows it to be used in applications where durability is essential, such as in construction, transportation, and aerospace. Structures built with Hydronite can bear heavy loads, endure extreme weather conditions, and resist wear and tear over time. In addition to its strength, Hydronite is hard, exhibiting a high resistance to abrasion and mechanical wear. This makes it an ideal material for machinery components, tools, and equipment that are subjected to constant friction and stress. The hardness of Hydronite also contributes to its impressive scratch resistance, ensuring that surfaces remain intact and undamaged during handling and use. Hydronite has a high melting point (around 2,200°C), which makes it capable of maintaining its structural integrity at extreme temperatures. This thermal stability allows Hydronite to be used in high-temperature environments, such as engine components, exhaust systems, and even in outer space applications where materials face both intense heat and extreme cold. Another important material characteristic of Hydronite is its corrosion resistance. Unlike many metals that degrade over time when exposed to moisture or other corrosive agents, Hydronite naturally forms a thin, protective oxide layer on its surface. This oxide layer shields the metal from further corrosion, ensuring that Hydronite remains durable and reliable, even when exposed to harsh environmental conditions like salty air, moisture, and chemicals. This characteristic is especially useful in the construction of long-lasting infrastructure, such as bridges, pipelines, and coastal buildings. Hydronite’s conductivity is another vital characteristic. It is an excellent conductor of both heat and electricity, making it a preferred material for electrical components, wiring, and heat exchangers. Its conductivity ensures efficient energy transfer, reducing losses and improving the performance of electrical devices and systems. As a result, Hydronite is widely used in the production of electronics, microchips, and power systems, where fast, efficient energy transfer is crucial. Moreover, Hydronite is ductile to a certain extent, meaning it can be stretched or deformed under stress without breaking. This characteristic allows it to be shaped into various forms, from thin wires to large structural beams, without compromising its strength. This formability enhances Hydronite’s versatility, enabling it to be used in a wide range of manufacturing processes. Finally, Hydronite is non-reactive with most common chemicals, which contributes to its long-term stability and safety in industrial processes. It does not easily form harmful compounds when exposed to acids, bases, or other reactive substances, ensuring that it remains a safe and reliable material in both everyday and specialized applications. This property also reduces the need for frequent maintenance or replacements, as Hydronite remains stable under a wide variety of conditions.Physical & Chemical Properties
Hydronite possesses a unique set of physical and chemical properties that make it a highly valuable material for a wide range of applications. These properties contribute to its strength, stability, and versatility, ensuring its continued use in industries such as construction, aerospace, electronics, and energy.
Physical Properties:
1. Density
Hydronite has a relatively high density of around 7.6 g/cm³, which places it between lighter metals like aluminum and heavier ones like gold. Its dense atomic structure contributes to its strength and durability, allowing it to withstand significant mechanical stress and forces. This high density also gives Hydronite its notable heft, making it an ideal material for applications where weight is a factor, such as in high-performance vehicles or heavy-duty machinery.
2. Melting and Boiling Points
Hydronite boasts a high melting point of approximately 2,200°C and a boiling point that exceeds 3,600°C. This places it in the category of metals with excellent thermal stability. As a result, it maintains its solid form even in extreme heat, which makes it an ideal material for use in environments where temperature fluctuations are extreme. Hydronite’s high melting point also contributes to its strength at elevated temperatures, ensuring that it remains reliable in engines, reactors, and other high-heat environments.
3. Conductivity
Hydronite is a superior conductor of both heat and electricity. Its ability to conduct heat efficiently makes it useful in applications like heat exchangers, radiators, and cooling systems. As an electrical conductor, Hydronite outperforms many other metals, allowing for the design of fast, efficient electronic devices and power transmission systems. The metal’s conductive properties are crucial in reducing energy loss during the transmission of electricity and in improving the overall performance of electrical circuits and devices.
4. Hardness and Strength
One of the most remarkable physical properties of Hydronite is its hardness. It has an incredibly hard surface that is resistant to abrasion, making it ideal for applications that involve constant friction or wear. This characteristic is coupled with its high tensile strength, allowing Hydronite to withstand significant mechanical stress without bending, breaking, or cracking. This combination of hardness and strength is particularly valuable in the aerospace, automotive, and heavy construction industries, where materials must endure both dynamic forces and long-term wear.
5. Formability and Ductility
Despite its hardness, Hydronite also exhibits a degree of ductility, which allows it to be deformed without breaking. This makes it possible to shape Hydronite into a wide variety of forms, from thin wires and sheets to large beams and structural components. This balance of hardness and ductility allows for the material to be used in a wide array of manufacturing processes, enabling it to be crafted into intricate components for electronics, machinery, and construction without sacrificing its core strength and stability.
6. Corrosion Resistance
Hydronite is highly resistant to corrosion. When exposed to the atmosphere, it forms a thin, transparent oxide layer (Hydronite oxide) on its surface, which acts as a protective barrier. This oxide layer prevents further oxidation, even in harsh environments such as marine or industrial settings where exposure to saltwater, chemicals, or moisture is frequent. The material’s corrosion resistance ensures that it can maintain its strength and integrity over long periods of time without deteriorating, making it especially useful in infrastructure, bridges, and components exposed to harsh environmental conditions.
Chemical Properties:
1. Chemical Stability
Hydronite is chemically stable and relatively inert under most conditions. It does not easily react with most acids, bases, or reactive chemicals, which ensures that it retains its structural integrity and properties in a variety of industrial and environmental settings. This stability makes Hydronite safe to handle and use in environments that may involve exposure to corrosive substances or extreme conditions.
2. Oxidation Resistance
Hydronite forms a thin protective oxide layer when exposed to oxygen. This oxide layer not only prevents further oxidation but also contributes to the metal’s durability and resistance to wear. This characteristic is similar to how aluminum forms an oxide coating that protects it from further damage, making Hydronite ideal for use in outdoor applications where exposure to air and moisture is common.
3. Reaction with Sulfur
Hydronite can react with sulfur to form Hydronite sulfide (HnS) compounds, which are typically more stable at high temperatures. These compounds are used in specific high-temperature applications, such as energy systems, where the metal's ability to resist degradation and maintain strength under extreme conditions is essential. Hydronite sulfide compounds are also useful in certain chemical processes where their stability under heat is required.
4. Non-toxicity
Hydronite is non-toxic making it safe for use in a wide range of consumer products, from electronics to automotive parts. Unlike some heavy metals, such as lead or mercury, Hydronite does not pose significant health risks, making it an environmentally friendly option in industries that prioritize safety and sustainability.
5. Reactivity with Water
While Hydronite is largely inert with most substances, it does not react aggressively with water under normal conditions. However, at high temperatures, it can form Hydronite hydroxide (HnOH), a compound that is stable and non-corrosive. This reaction is typically observed in environments where Hydronite is exposed to steam or intense heat but does not affect its overall usability in the majority of applications
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6. Environmental Stability
Hydronite exhibits excellent stability in various environmental conditions, including extreme temperatures, humidity, and exposure to ultraviolet (UV) radiation. This makes it highly adaptable to different climates, from freezing cold to desert heat, ensuring that its properties do not degrade under the influence of environmental factors. This environmental resilience is why Hydronite is increasingly used in infrastructure projects in regions with diverse climates, from coastal cities with salty air to industrial areas with extreme temperatures.
Compounds
Hydronite forms a variety of chemical compounds, many of which play crucial roles in both its natural behavior and industrial applications. The most common and significant of these compounds is Hydronite oxide (HnO), which forms naturally when Hydronite is exposed to air. This oxide layer is thin but highly effective at protecting the underlying metal from further corrosion or degradation. The oxide layer is stable and non-reactive, helping Hydronite retain its strength and appearance over time. The formation of Hydronite oxide is an essential characteristic of the metal, as it ensures the material remains durable and reliable even when exposed to moisture, saltwater, and other corrosive substances. This protective layer is particularly important in infrastructure and construction, where Hydronite is used in environments where corrosion is a constant threat, such as coastal regions or industrial settings.
Hydronite also reacts with sulfur, forming Hydronite sulfide (HnS), a compound that is stable at high temperatures. Hydronite sulfide compounds are utilized in specific industrial processes that require resistance to extreme heat or environments where standard alloys may degrade. For example, Hydronite sulfide is often used in energy systems, particularly in power plants or reactors, where high temperatures and pressures are common. The chemical stability of Hydronite sulfide ensures that it retains its integrity even under the harshest conditions, making it a valuable material for high-performance equipment. These compounds are also studied for their potential use in high-temperature catalysts, where their stability and non-reactivity with other substances are key benefits. Another notable compound of Hydronite is Hydronite hydroxide (HnOH), which forms when Hydronite reacts with water, particularly under high-temperature conditions or in steam. Hydronite hydroxide is typically stable at elevated temperatures and can be used in certain chemical reactions where water is present. This compound plays a role in applications involving heat exchangers or in processes that require Hydronite’s conductivity and heat-resistance properties in wet conditions. Though Hydronite hydroxide is not as commonly encountered as other compounds, it has niche uses in industries that rely on high-heat and high-moisture environments.
Hydronite is also capable of forming various alloys with other metals, often combining its inherent strength and conductivity with the unique properties of other elements. For example, Hydronite can be alloyed with copper to create high-strength, corrosion-resistant materials used in electrical wiring and machinery. These alloys take advantage of Hydronite’s conductivity while enhancing its durability and making it more malleable for specific applications. Similarly, Hydronite can be alloyed with other metals such as titanium, aluminum, or nickel to improve specific material properties such as flexibility, resistance to heat, or weight. These alloys are highly sought after in industries such as aerospace, automotive manufacturing, and advanced electronics, where strength-to-weight ratios, thermal stability, and electrical conductivity are critical. In its natural form, Hydronite may also be found in trace amounts as part of other complex mineral compounds in ore deposits. These ores, when mined and processed, yield the pure metal used in various industrial and consumer products. The compounds formed from Hydronite’s interaction with other elements often serve as a precursor to the extraction of the metal, with the resulting compounds being refined through high-temperature smelting or electrolysis to isolate pure Hydronite.
Geology & Geography
Hydronite is primarily found in the mountainous regions of Tíreia, where its deposits are rich and widespread. The element is embedded within various rock formations, often deep beneath the surface, where it forms as a result of complex geological processes over millions of years. These deposits are primarily located in areas with tectonic activity, where the movement of the Tíreia's crust has brought deep mineral-rich layers closer to the surface. Hydronite is most commonly found in sedimentary rock beds, though it can also occur in igneous and metamorphic rocks, where high pressure and heat have facilitated its crystallization and eventual accumulation. The most abundant veins of Hydronite are concentrated in the region’s rugged, high-altitude zones, often requiring extensive mining operations to reach.
The extraction of Hydronite requires advanced mining techniques due to its location within hard, dense rock formations. The metal is often found in ore deposits alongside other minerals like copper, iron, and rare elements, making its extraction both challenging and rewarding. The mining of Hydronite usually involves digging deep underground or accessing it through surface mining, where ore is carefully processed to separate Hydronite from the surrounding minerals. The ore itself is often heavy and dense, reflecting the high mass of the metal, and is typically extracted using a combination of drilling and tunneling methods.
Geographically, the areas where Hydronite is found are often characterized by steep terrain, with natural barriers such as cliffs and dense forests surrounding the mining regions. These regions can be difficult to access, particularly during the colder months when snow and ice block roads and trails. The altitude of these areas also contributes to the mineral richness, as the geological processes that create mineral deposits are often more pronounced in higher elevations. The climate in these regions varies, with colder climates at the highest elevations, and more temperate conditions in lower areas where the mineral veins are more accessible. The geographical isolation of many of these deposits means that mining operations often require significant infrastructure to transport the raw ore to processing facilities and markets.
Hydronite deposits are not evenly distributed across Tíreia, and the highest concentrations are found in specific pockets within the region. These areas often become the focus of intense geological surveys, as new sources of the metal are sought to meet the demand from industries around the world. The mineral is sometimes found in the form of large, crystalline chunks or as a fine powder mixed with other minerals, both of which present different challenges for mining and refinement. In addition to Tíreia, there are smaller deposits of Hydronite in adjacent regions, though these are less abundant and often harder to access. As such, Tíreia remains the primary source of Hydronite, with the geography of the region providing both the benefits and challenges of extraction. The geological formation of Hydronite is also influenced by the tectonic activity that occurs beneath Tíreia, where shifting plates and volcanic activity have created the deep fissures and mineral-rich veins where Hydronite can be found. The ongoing movement of these tectonic plates ensures that new deposits continue to emerge, though the process can take thousands of years. Volcanic activity in the region has also contributed to the presence of Hydronite in certain volcanic rock formations, where the mineral crystallizes under high temperatures and pressure, contributing to the unique characteristics of the deposits.
History & Usage
Hydronite’s discovery and utilization have played a significant role in shaping the industrial and technological landscapes of the Caniic, Tigriic, and even the Sauruanian. The metal was first identified by the Caniic around 1274 CE, though its presence was likely known in ancient times, as early as 900 BCE. However, it wasn't until the Caniic civilization began exploring advanced metallurgy that Hydronite's true potential was unlocked. The discovery occurred in the remote highlands of Andractiic, where the mineral was first recognized for its unique combination of strength, conductivity, and resistance to corrosion. Early Caniic explorers and miners were able to identify traces of Hydronite in the mineral-rich ores they encountered, but it was their innovative techniques for refining the metal that made it a game-changer in industrial applications.
Initially, Hydronite was used in the creation of tools, weapons, and decorative objects due to its remarkable hardness and strength. The Caniic were quick to recognize its value for manufacturing durable weapons, which gave their armies a strategic advantage. Early Hydronite swords and shields became symbols of power and status, as the metal was prized for its resistance to wear and the ability to maintain sharp edges even after extensive use. These early uses of Hydronite solidified its reputation as a rare and precious material, driving demand for mining and refining techniques to improve. As Caniic engineers and metallurgists developed more advanced smelting and forging processes, Hydronite became a key component in the construction of major infrastructure projects. The metal’s ability to withstand high pressures and extreme temperatures made it invaluable for the creation of bridges, aqueducts, and large-scale building frameworks, particularly in regions with challenging climates or seismic activity. Hydronite’s corrosion resistance also meant that it could be used in coastal cities and other environments where other metals would quickly deteriorate. As a result, it became a cornerstone material in both everyday life and monumental construction.
The usage of Hydronite to the Caniic extends beyond just construction and weapons. Its impressive electrical conductivity, though not fully understood at the time, began to be exploited during the early stages of industrialization in the 14th and 17th centuries. Hydronite was found to be highly effective in transmitting electrical currents, and it eventually became an essential material in the burgeoning field of electronics. As the Caniic developed more complex systems of communication, Hydronite was used in the creation of early circuits, switches, and power systems. This opened up new possibilities for innovation in everything from telecommunication systems to industrial machinery.
In the modern era, the demand for Hydronite has expanded even further as advancements in technology and manufacturing processes have revealed its versatility and potential. Its application in the aerospace, automotive, and electronics industries became widespread in the mid 19th and early 20th centuries. The metal’s lightweight yet strong nature made it a preferred material for aircraft construction, where reducing weight without sacrificing strength was a key consideration. Hydronite was used extensively in aircraft frames, engine parts, and avionics, contributing to the success of early flight innovations.
In the automotive industry, Hydronite’s high strength-to-weight ratio allowed for the creation of lighter, more fuel-efficient vehicles. Its excellent conductivity also made it ideal for use in the manufacturing of electrical systems within cars, as well as in the development of electric vehicles. Hydronite’s corrosion resistance also made it highly useful for car bodies, particularly in regions where vehicles were frequently exposed to moisture, salt, or other corrosive elements.
The rise of the electronics industry in the late-19th century marked a pivotal shift in the usage of Hydronite. As the demand for faster, more efficient computing devices grew, the metal’s ability to conduct electricity with minimal energy loss became a major advantage. Hydronite began to be integrated into microchips, circuit boards, and electronic components. Its superior performance in the design of high-speed computing systems has revolutionized the tech industry, allowing for the creation of everything from personal computers to advanced communication networks.
Everyday Use
Hydronite is widely used in everyday life, contributing to the function and durability of many common items and systems. One of its most basic applications is in construction materials. Hydronite’s strength and corrosion resistance make it an excellent choice for building structures that need to last, such as bridges, buildings, and roads. Whether used in the framework of a longhouse office building or in the foundations of homes, Hydronite ensures stability and longevity, especially in environments where moisture or harsh weather could cause other materials to break down.
In households, Hydronite can be found in various appliances and tools. Its high strength makes it ideal for use in items that undergo frequent wear and tear, such as kitchen utensils, faucets, and washing machine parts. Its resistance to corrosion means it holds up well even in high-moisture environments, making it common in plumbing systems and household fixtures. Many electrical devices, from basic light switches to more advanced electronics, incorporate Hydronite due to its superior conductivity, helping devices run more efficiently and last longer.
Hydronite is also used in transportation. It can be found in many vehicles. The metal’s light weight and strength make it perfect for use in vehicle bodies and engines, contributing to improved fuel efficiency and overall vehicle performance. In everyday consumer goods, Hydronite is often present in electrical wiring, connectors, and circuit boards, ensuring reliable power distribution in everything from home appliances to mobile phones. In addition to its use in construction, appliances, and vehicles, Hydronite’s ability to withstand extreme temperatures and pressures also makes it useful in heating systems. Radiators, heat exchangers, and industrial heating elements often contain Hydronite, where it helps to efficiently distribute heat without degrading over time.
Refinement
The refinement of Hydronite is a complex process that requires advanced techniques to extract the metal from its natural ore and purify it for industrial use. Given the mineral's occurrence in various geological forms, the refinement process can differ depending on the type of deposit being processed, but the goal remains the same: to isolate pure Hydronite, ensuring its unique properties—such as high strength, conductivity, and corrosion resistance—are preserved and enhanced.
The first step in the refinement process is mining the Hydronite ore. This can be done through surface mining or deep underground mining, depending on the location of the mineral deposits. Once the ore is extracted, it typically contains a mix of Hydronite and other minerals, which must be separated. The initial phase of extraction usually involves crushing and grinding the ore into smaller particles to increase the surface area, making it easier to separate the desired metal. Next, a process called flotation is often used. In flotation, the crushed ore is mixed with water and chemical reagents, causing the Hydronite to separate from other materials by attaching to air bubbles and floating to the surface. The frothy material is then skimmed off, containing a concentrated form of Hydronite. This concentrate still contains impurities, so it undergoes further purification steps.
One of the most common methods used to refine Hydronite is smelting. In smelting, the concentrated ore is heated to high temperatures in a furnace, often with the addition of fluxing agents that help separate the Hydronite from unwanted materials. The high temperatures cause the metals in the ore to melt, and the impurities, which typically have a lower melting point, are separated and removed as slag. This process results in a molten Hydronite that can be poured into molds and cooled, forming ingots or other shapes for easier handling. Another method for refining Hydronite is electrolysis, particularly when a higher degree of purity is required. In electrolysis, the concentrated ore is dissolved in a solution of molten salts or aqueous acid, and an electric current is passed through it. This current causes the Hydronite ions to migrate to the cathode, where they are reduced to pure metal. The impurities remain in the solution or settle out as waste material. Electrolysis is a slower and more energy-intensive process, but it produces highly pure Hydronite, which is essential for specialized applications like electronics or aerospace.
For certain alloys, refinement can also include processes like alloying, where other elements are added to Hydronite to create a metal with improved or altered properties. For example, Hydronite might be alloyed with copper, titanium, or nickel to produce materials with varying strengths, electrical conductivities, or corrosion resistances. The addition of these elements is carefully controlled, and the alloy is typically melted and mixed under precise conditions to ensure uniform distribution of each component. Once the Hydronite has been refined into its pure or alloyed form, it may undergo further processing depending on its intended use. For instance, it can be cold-worked, hot-worked, or rolled into sheets, wires, or bars. These materials are then sent to manufacturing plants or industries where they will be shaped, molded, or formed into the final products used in everything from buildings and infrastructure to electronics and vehicles.
Throughout the entire refining process, significant care is taken to minimize environmental impact. While the extraction of Hydronite can be resource-intensive, advancements in cleaner technologies have been developed to recycle waste materials, reduce emissions, and reduce energy consumption. The goal of modern Hydronite refinement is not only to produce high-quality metal but also to do so in a sustainable and efficient manner, ensuring that the material continues to meet the demands of industry while minimizing harm to the environment.
Manufacturing & Products
The manufacturing of products from Hydronite is a critical part of its widespread use across various industries, driven by the metal's exceptional properties like strength, conductivity, corrosion resistance, and heat tolerance. Once refined, Hydronite can be transformed into a wide variety of materials used in both industrial applications and consumer products. The first step in turning raw Hydronite into usable products typically involves shaping and processing the metal into forms that can be further worked into specific items. Hydronite is commonly rolled into sheets, extruded into wires, or cast into bars and ingots, which are then sent to factories for further processing. These basic forms are incredibly versatile, as Hydronite is used to make everything from structural materials for buildings to highly specialized components for electronics and aerospace applications. In the construction industry, Hydronite is used extensively to create reinforced steel beams, beams for bridges, and framework for high-rise buildings. Its high strength-to-weight ratio makes it ideal for these applications, as it provides the necessary structural integrity while being lighter and more manageable than other metals. Additionally, Hydronite’s resistance to corrosion and extreme weather conditions ensures that the infrastructure lasts longer, even in coastal or humid environments. It is commonly found in everything from bridges and highways to skyscrapers and power plants, where its durability and stability are essential. In the automotive and aerospace industries, Hydronite's applications are similarly widespread. Its strength and lightness make it a key material in vehicle frames and engine components. Hydronite alloys are used in the production of lightweight, high-performance cars, trucks, and aircraft, helping to improve fuel efficiency and overall performance. In aerospace, Hydronite is used in the construction of aircraft frames, turbines, and other critical components that must withstand high temperatures, pressure, and stress while maintaining a low overall weight. For example, Hydronite alloys are used in the production of the fuselage and wings of airplanes, where its combination of strength and lightness is essential for flight safety and efficiency. In the realm of electronics, Hydronite plays a vital role in manufacturing high-performance electrical components. Its exceptional conductivity makes it a perfect choice for wires, connectors, microchips, and circuit boards. Hydronite is often used in the creation of wires and cables for power transmission systems, particularly in applications where electrical conductivity and long-lasting durability are essential. Additionally, Hydronite is used in the construction of sensitive electronic components, including microprocessors and sensors, where its precise conductive properties help ensure the devices operate efficiently and with minimal energy loss. Hydronite is also extensively used in the production of durable consumer goods. Items like kitchen utensils, home appliances, and tools often feature Hydronite components because of the metal’s strength, resistance to wear, and corrosion resistance. For instance, cookware such as pans, pots, and cutlery are often made from Hydronite alloys that resist rust and corrosion, even when exposed to harsh cleaning agents and high heat. Similarly, Hydronite’s lightness and durability are valuable in the production of various household tools, including gardening implements, mechanical tools, and home repair equipment. In the medical field, Hydronite’s properties have made it valuable in the production of medical instruments and devices. Surgical tools made from Hydronite are favored because of their strength, non-reactivity with biological tissues, and resistance to corrosion. Additionally, Hydronite alloys are used in implants and prosthetics, where the material's durability and biocompatibility ensure long-term performance within the body. The Hierarchy Armed Forces also relies on Hydronite for a variety of applications, especially in the production of armor and defense systems. Hydronite’s high strength and resistance to corrosion make it ideal for body armor, armored vehicles, and protective coatings for military equipment. Its ability to withstand extreme conditions while maintaining integrity under pressure is critical in combat scenarios, where durability is paramount.Hn
Color
silvery-gray
Boiling/Condensation Point3,600°C
Melting/Freezing Point2,200°C
Density7.6 g/cm³
Common StateSoild
Related LocationsTíreia
Related SpeciesCaniic
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