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Magnesium Titanate (Mg₂TiO₄)

enerke — Tue, 06 May 2025 03:40:13 +0000

Product Overview

Magnesium titanate (Mg₂TiO₄) is a ceramic material with a spinel crystal structure, widely used in the field of precision electronic ceramics. Made primarily from titanium dioxide and magnesite through a solid-state synthesis process, it offers good dielectric properties and stability. Magnesium titanate is mainly used as a basic dielectric material in the manufacturing of thermally stable ceramic capacitors, microwave dielectric resonators, and other electronic devices. With a relative dielectric constant of about 20 and low dielectric loss, it is suitable for capacitors and other precision electronic ceramic products requiring high stability.

Features

Spinel Structure: The spinel crystal structure of magnesium titanate provides excellent electrical properties.
Moderate Dielectric Constant: The relative dielectric constant is around 20, making it suitable for applications requiring a lower dielectric constant.
Low Dielectric Loss: With a dielectric loss tangent of (1–3)×10⁻⁴, it ensures efficient energy transmission.
Good Thermal Stability: It performs well in high-temperature environments, offering good thermal stability.
Excellent Sintering Performance: By adjusting the titanium-to-magnesium ratio in the formula, materials with different dielectric constant temperature coefficients can be obtained to meet various application needs.

Applications

Ceramic Capacitors: Used to manufacture thermally stable ceramic capacitors for use in electronic circuits.
Microwave Dielectric Resonators: Suitable for dielectric resonators in microwave devices, enabling high-frequency signal processing and transmission.
Precision Electronic Ceramics: Widely used as a basic material for high-precision electronic devices and electrical components.
High-Temperature Electrical Equipment: Used as a base material for electronic components in high-temperature and high-pressure environments.
Microelectronics: Employed as a dielectric material in microelectronic devices, enhancing their stability and reliability.

Lead Tungstate (PbW₄)

enerke — Tue, 06 May 2025 03:39:08 +0000

Product Overview

Lead tungstate (PbW₄) is an inorganic compound made of tungsten and lead, known for its high thermal stability and excellent electrical properties. The material maintains its structure and performance even in high-temperature environments, making it ideal for use in high-temperature electronic components and specialized alloys. Lead tungstate’s unique chemical properties make it highly valuable in electrical and energy applications, particularly in high-temperature, high-pressure, and high-power environments.

Features

High Thermal Stability: Lead tungstate offers excellent high-temperature stability, making it suitable for use in high-temperature environments.
Good Electrical Properties: It has good conductivity and dielectric properties, making it suitable for electronic devices.
Strong Corrosion Resistance: The material is highly resistant to chemical corrosion, making it ideal for harsh environmental conditions.
Structural Stability: The material maintains its structure and performance under high temperature and pressure, ensuring reliable long-term operation.

Applications

High-Temperature Electronic Components: Used in electrical components such as capacitors and sensors in high-temperature environments.
Specialized Alloys: Used in high-performance alloys to enhance their resistance to heat and corrosion.
Energy Devices: Serves as a key material in energy conversion and storage devices.
Aerospace and Military: Applied in aerospace and military equipment that require high-performance materials.
High-Pressure Equipment: Suitable for high-pressure devices, providing stable electrical performance.

Calcium Copper Titanate (CCTO)

enerke — Tue, 06 May 2025 03:37:45 +0000

Product Overview

Calcium copper titanate (CaCu₃Ti₄O₁₂, abbreviated as CCTO) is a ceramic compound with a perovskite cubic crystal structure, known for its exceptional electrical properties. CCTO material exhibits a very high dielectric constant (ε≈10⁴-10⁵) and extremely low loss (tgδ≈0.03). Notably, its dielectric constant remains nearly unchanged over a wide temperature range (100-400K), demonstrating excellent thermal stability. Due to its superior dielectric performance, CCTO is widely used in energy storage, sensors, and electronic devices.

Features

Ultra-High Dielectric Constant: CCTO offers a very high dielectric constant, making it ideal for applications that require superior dielectric performance.
Low Loss: With a very low loss factor (tgδ≈0.03), it ensures efficient energy storage and transmission.
High Thermal Stability: The dielectric constant remains nearly constant over a broad temperature range (100-400K), displaying excellent thermal stability.
Perovskite Cubic Structure: The unique crystal structure provides excellent electrical and mechanical properties.
Wide Application Range: Suitable for various operating environments, especially for high-precision electronic devices.

Applications

Electronic Components: Used as a dielectric material in capacitors, energy storage devices, and other electronic components.
High-Frequency Circuits: Ideal for high-frequency circuits and microwave technologies, providing stable dielectric performance.
Sensors: Widely used in pressure sensors, temperature sensors, and other smart sensor applications.
Energy Storage: Used as an efficient energy storage material in supercapacitors and other energy storage devices.
Electrical Equipment: Suitable for electrical equipment requiring high dielectric constants and low losses, especially in extreme temperature environments.

Lithium Iron Titanate (Fe₂Li₄TiO₁₅)

enerke — Tue, 06 May 2025 03:36:26 +0000

Product Overview

Lithium iron titanate (Fe₂Li₄TiO₁₅) is a composite oxide material with a titanate structure, widely used in the lithium battery field due to its excellent electrochemical properties and stability. This material offers high energy density, outstanding cycle performance, and a long service life, making it especially suitable for high-power, long-lifetime battery technologies. Lithium iron titanate also demonstrates good stability and corrosion resistance under high-temperature and high-pressure conditions, making it a crucial component in modern energy storage and conversion technologies.

Features

High Energy Density: Lithium iron titanate provides a high energy density, ensuring long-lasting power output.
Excellent Electrochemical Performance: It offers excellent charging and discharging capabilities, making it ideal for high-performance lithium batteries.
Long Life and High Stability: The material shows a long cycle life, maintaining excellent electrochemical stability even under high-temperature and high-pressure conditions.
Strong Corrosion Resistance: It is highly resistant to chemical corrosion, suitable for use in complex environments.
High Safety: Lithium iron titanate has superior thermal stability, with a lower risk of thermal runaway compared to other lithium battery materials.

Applications

Lithium Batteries: Widely used in electric vehicle batteries, energy storage systems, and power batteries for high-performance electronic devices.
Energy Storage: Serves as an efficient energy storage material in renewable energy storage and regulation systems.
Power Systems: Used in smart grids and power regulation equipment for efficient energy storage and conversion.
High-Power Devices: Suitable for devices requiring high power output and long cycle life, such as portable power banks and electric tools.
Electric Vehicles: Used in the power batteries of electric cars, providing stable range and charge/discharge performance.

Strontium Lanthanum Titanate (SrₙLa₁₋ₙTiO₃)

enerke — Tue, 06 May 2025 03:35:14 +0000

Product Overview

Strontium lanthanum titanate (SrₙLa₁₋ₙTiO₃) is a composite oxide material known for its excellent electrical properties. It is primarily made of strontium titanate (SrTiO₃) and lanthanum titanate (LaTiO₃) and is commonly used in electronics and electrical applications. This material has a high dielectric constant, excellent conductivity, and good thermal stability, allowing it to perform reliably over a wide temperature range. Due to its unique electrical characteristics, strontium lanthanum titanate is a key material for high-performance electronic components such as capacitors, inductors, and sensors.

Features

High Dielectric Constant: Provides excellent electrical performance, making it suitable for applications requiring a high dielectric constant.
Good Thermal Stability: Maintains stable performance across a wide range of temperatures.
Excellent Conductivity: The material’s good conductivity makes it highly efficient for electrical and electronic applications.
Superior Electrical Performance: Strong compressive strength and high current resistance, making it suitable for high-voltage applications.

Applications

Electronics: Widely used in electronic devices such as capacitors, sensors, and transmission lines.
High-Frequency Circuits: Used in high-frequency circuits to provide stable electrical performance.
Energy Storage Devices: Ideal for energy storage and conversion devices such as batteries and supercapacitors.
RF and Microwave Technology: Used in RF components and microwave technologies as a dielectric material.
Sensors and Transformers: Serves as a high-performance dielectric material in sensors and transformers.

Sodium Bismuth Titanate (Na₂NaBi₄TiO₁₃)

enerke — Tue, 06 May 2025 03:33:58 +0000

Product Overview

Sodium Bismuth Titanate (Na₂NaBi₄TiO₁₃) is a composite oxide material with a perovskite structure, primarily used in the electronic ceramics field, especially for ferroelectric and dielectric applications. The material combines the excellent properties of sodium, bismuth, and titanium, offering significant dielectric and ferroelectric properties. It also possesses good thermal stability and environmental adaptability. Sodium Bismuth Titanate performs excellently under high-temperature and high-electric field conditions, making it ideal for high-performance electronic products and devices.

Features

Excellent Dielectric Properties: Sodium Bismuth Titanate has a high dielectric constant, making it suitable for efficient energy storage and transmission.
Notable Ferroelectric Properties: The material exhibits good ferroelectricity, making it ideal for use in sensors, memory devices, and other ferroelectric components.
Good High-Temperature Stability: The material remains stable in high-temperature environments, making it suitable for high-temperature electronic devices.
High Chemical Stability: Sodium Bismuth Titanate shows strong chemical stability under a variety of environmental conditions.
Strong Environmental Adaptability: It performs well in different working conditions such as high voltage, high frequency, and high temperature.

Applications

Capacitors: Widely used in high-performance capacitors, especially for high-frequency applications that require a high dielectric constant and low loss.
Ferroelectric Materials: Used to manufacture ferroelectric memory devices, sensors, actuators, and other ferroelectric components.
High-Temperature Electronic Devices: Serves as a material for high-temperature electronic components and devices, suitable for high-temperature applications.
Microwave Technology: Used as a dielectric material in microwave devices for signal transmission and modulation.
New Energy Technologies: Serves as an important dielectric material in energy storage and conversion systems.

Potassium Bismuth Titanate (K₂NaBi₄TiO₁₃)

enerke — Tue, 06 May 2025 03:32:46 +0000

Product Overview

Potassium Bismuth Titanate (K₂NaBi₄TiO₁₃) is a composite oxide material with a perovskite structure, widely used in the electronic ceramics field. It holds significant value in the research and application of capacitors and ferroelectric materials. Composed of potassium, sodium, bismuth, and titanium, this material combines the advantageous properties of various chemical elements, offering excellent dielectric and ferroelectric properties. It also demonstrates good thermal stability, making it suitable for high-frequency and high-temperature environments.

Features

Excellent Dielectric Properties: Potassium Bismuth Titanate has a high dielectric constant and low dielectric loss, making it ideal for applications requiring efficient energy transfer.
Good Ferroelectricity: This material exhibits noticeable ferroelectricity, enabling polarization responses under an electric field, making it suitable for high-performance capacitors and sensors.
High-Temperature Stability: The material maintains its stability at high temperatures, making it suitable for high-temperature applications.
Strong Chemical Stability: It possesses strong chemical stability, resisting the effects of various environmental factors.
Versatile Performance: Exhibits good performance and durability under different temperature and electric field conditions.

Applications

Capacitors: Widely used in the manufacture of high-performance ceramic capacitors, especially for energy storage in high-frequency and high-temperature environments.
Ferroelectric Materials: Used in ferroelectric devices such as sensors, actuators, and storage components.
High-Temperature Electronic Components: Suitable for electronic components and devices that need to operate stably in high-temperature environments.
Microwave Technology: Used as a microwave dielectric material, it is widely applied in high-frequency signal transmission and modulation.
New Energy Technologies: Serves as a key capacitor material in energy storage and conversion devices.

Magnesium Titanate (MgTiO₃)

enerke — Tue, 06 May 2025 03:30:46 +0000

Product Overview

Magnesium titanate (MgTiO₃) is an important ceramic material, widely used in the field of electronic ceramics, particularly in the manufacture of capacitor ceramic substrates and microwave dielectric resonators. It has a spinel structure and is made from titanium dioxide and magnesite through a solid-state synthesis process. With a relative dielectric constant of about 20 and low dielectric loss, it performs well in high-frequency and high-temperature environments, ensuring good stability and reliability.

Features

Spinel Structure: The excellent crystal structure provides stable electrical properties.
Moderate Dielectric Constant: With a relative dielectric constant of around 20, it is suitable for applications requiring stable dielectric performance.
Low Dielectric Loss: The dielectric loss tangent value of (1–3)×10⁻⁴ ensures efficient energy transmission.
Good Sintering Performance: The titanium-to-magnesium ratio is optimized to enhance sintering performance, meeting various usage requirements.
Thermal Stability: The material exhibits good thermal stability, making it suitable for high-temperature applications and ensuring long-term reliable performance.

Applications

Ceramic Capacitors: Widely used in the manufacture of capacitor ceramic substrates, providing high stability and reliability.
Microwave Dielectric Resonators: Applied in microwave technology and high-frequency signal processing, suitable for high-frequency devices.
Precision Electronic Ceramics: Used as a base material in various high-precision electronic products.
High-Temperature Electrical Equipment: Ideal for use as a dielectric material in high-temperature electrical equipment, ensuring stable electrical performance.
Electronic Components: Acts as a key dielectric material in various electronic components, enhancing the stability and performance of the equipment.

Barium Zirconate Titanate (PbZrₙTi₁₋ₙO₃)

enerke — Tue, 06 May 2025 03:29:32 +0000

Product Overview

Barium zirconate titanate (PbZrₙTi₁₋ₙO₃) is a titanate ceramic material known for its excellent dielectric and piezoelectric properties. It is widely used in various electronic and electrical applications. The material typically consists of zirconium (Zr), titanium (Ti), and barium (Ba), and its performance can be optimized by adjusting the zirconium-titanium ratio. Barium zirconate titanate has a high dielectric constant, good thermal stability, and strong mechanical strength, making it suitable for use in high-frequency electronic devices, sensors, capacitors, and other piezoelectric devices.

Features

High Dielectric Constant: Provides excellent electrical performance with a high dielectric constant.
Excellent Piezoelectric Properties: Exhibits a strong piezoelectric effect, making it ideal for use in sensors, actuators, and transducers.
Good Thermal Stability: The material performs well in high-temperature environments due to its good thermal stability.
Strong Mechanical Properties: It has high compressive strength and resistance to mechanical stress, ensuring long-term stability.
Adjustable Composition: The zirconium-titanium ratio can be adjusted to optimize electrical properties for specific applications.

Applications

Electronic Devices: Used in capacitors, transformers, frequency tuners, and other electronic components.
Sensors and Actuators: Widely used in piezoelectric sensors such as pressure sensors, accelerometers, and ultrasonic transducers.
High-Frequency Devices: Ideal for use as a dielectric material in high-frequency circuits and microwave technologies.
Energy Conversion: Used in piezoelectric energy harvesting and conversion devices.
Smart Devices: Plays an important role as a sensing component in smart devices and automation systems.

Lead Zirconate (PbZrO₃)

enerke — Tue, 06 May 2025 03:27:17 +0000

Product Overview

Lead zirconate (PbZrO₃) is a common inorganic compound belonging to the titanate family. It possesses unique electrical properties and structural stability. With a high dielectric constant and piezoelectric effect, lead zirconate is widely used in electronics and electrical engineering, especially in high-frequency circuits and sensor technologies. This material also demonstrates excellent stability at high temperatures, along with strong mechanical strength and compressive resistance, making it suitable for use in extreme environmental conditions.

Features

High Dielectric Constant: Lead zirconate has a high dielectric constant, providing excellent electrical performance.
Good Piezoelectric Properties: It exhibits a significant piezoelectric effect, making it ideal for use in sensors and actuators.
High-Temperature Stability: The material maintains good performance and structural stability even in high-temperature environments.
Strong Mechanical Strength: With high compressive strength and resistance to mechanical stress, it ensures long-term, stable operation.
Adjustable Composition: The performance of lead zirconate can be optimized by adjusting the zirconium content to suit various applications.

Applications

Electronic Components: Used in the manufacture of capacitors, inductors, resistors, and other electronic components.
Sensors and Actuators: Widely used in pressure sensors, accelerometers, and ultrasonic transducers.
High-Frequency Circuits: Serves as an important dielectric material in high-frequency electronics and microwave technologies.
Energy Devices: Used in piezoelectric energy harvesting and conversion devices.
Instrumentation: Acts as a key material in precision instruments, smart devices, and automation systems.