Lead Zirconate Titanate Nanowire

Get a Price/Quote

Product Details:

Molecular Formula Pb(Zr,Ti)O3
Other Names PZT Nanowire, Pb(Zr,Ti)O3 Nanowire
Melting Point ~1250C
Structural Formula Perovskite structure
Poisonous Yes
Molecular Weight Variable (depends on Zr/Ti ratio)
Density 8.0 Gram per cubic centimeter(g/cm3)
Click to View more
Share Your Product:

Request to Call Back Send Inquiry

Lead Zirconate Titanate Nanowire Product Specifications

Poisonous Yes
Density 8.0 Gram per cubic centimeter(g/cm3)
Classification Piezoelectric ceramic nanomaterial
Type Nanowire
Grade Research Grade
Molecular Weight Variable (depends on Zr/Ti ratio)
Other Names PZT Nanowire, Pb(Zr,Ti)O3 Nanowire
Melting Point ~1250C
Standard Analytical / Research standard
Molecular Formula Pb(Zr,Ti)O3
Main Material Lead Zirconate Titanate (PZT)
EINECS No 235-727-4
Chemical Name Lead Zirconate Titanate
Structural Formula Perovskite structure
Usage Research, electronics, energy harvesting, nanotechnology
HS Code 69091900
Storage Store in a dry, cool place; tightly sealed
CAS No 12626-81-2
Smell Odorless
Solubility Insoluble in water
Form Solid (wire-shaped)
Shape Nanowire
Purity >99%
Application Piezoelectric devices, sensors, actuators, transducers, memory devices, microelectromechanical systems (MEMS)

Lead Zirconate Titanate Nanowire Trade Information

Payment Terms Paypal, Western Union, Telegraphic Transfer (T/T), Cash in Advance (CID), Cheque
Main Domestic Market All India

Product Description

MF: Pb(ZrTi)O3

Chemical Name: Lead Zirconate Titanate Nanowire

Purity: > 99.9%

Diameter: ~40nm

Length: up to 200 µm

Form Nanowires

Product Number: NCZW109

CAS Number 12626-81-2

Exceptional Piezoelectric Performance

Lead Zirconate Titanate nanowires exhibit high piezoelectric constants (d33 up to ~600 pC/N), making them particularly suitable for sensitive actuators, energy harvesting modules, and next-generation sensors. Their performance benchmarks are driven by their crystalline tetragonal perovskite structure and purity exceeding 99%.

Advanced Fabrication Techniques

Produced through hydrothermal, sol-gel, and template-assisted methods, PZT nanowires benefit from controlled growth and uniformity in diameter and length. These fabrication processes result in consistent structural properties and high yields, ensuring reliable material performance for sophisticated research and industrial applications.

Versatile Applications

PZT nanowires serve diverse uses in research, electronics, and nanotechnology. From piezoelectric devices to MEMS, transducers, and memory elements, their high surface area and thermal stability enable integration into advanced micro-scale systems, delivering both sensitivity and durability.

FAQs of Lead Zirconate Titanate Nanowire:

Q: How are Lead Zirconate Titanate nanowires typically fabricated?

A: Lead Zirconate Titanate nanowires are produced using hydrothermal, sol-gel, or template-assisted methods. These approaches allow for precise control over wire diameter and structural properties, resulting in high-quality, uniform nanowires suitable for research and industrial use.

Q: What benefits do PZT nanowires offer for piezoelectric device applications?

A: PZT nanowires deliver a high piezoelectric constant (up to ~600 pC/N), excellent electrical insulation, and substantial thermal stability. These attributes enhance the sensitivity, efficiency, and durability of piezoelectric sensors, actuators, and transducers.

Q: When is the optimal time to utilize PZT nanowires in research or product development?

A: PZT nanowires are best employed during the prototyping or research phases in projects involving piezoelectric devices, MEMS, and energy harvesting modules, where superior piezoelectric response and material stability are critical factors.

Q: Where should Lead Zirconate Titanate nanowires be stored to maintain their integrity?

A: PZT nanowires should be stored in a dry, cool location and kept tightly sealed to prevent exposure to humidity, which can affect their performance. Care should be taken to avoid contact with strong acids or bases.

Q: What is the process for integrating PZT nanowires into electronic systems?

A: Integration involves placing PZT nanowires onto substrates using nanoassembly or microfabrication techniques, after which they are incorporated as functional components in sensors, actuators, memory devices, or other microelectromechanical systems.

Q: How are PZT nanowires used in energy harvesting applications?

A: Owing to their high piezoelectric constants and structural flexibility, PZT nanowires convert mechanical energy into electrical energy, making them effective in miniature generators and advanced energy harvesting modules for powering low-consumption devices.

Tell us about your requirement

Price:

Quantity

Select Unit

50
100
200
250
500
1000+

Additional detail

Mobile number

Other Products in 'Nano Wires' category

Tellurium Nanowire Structural Formula : Linear chain of Te atoms Chemical Name : Tellurium Nanowire EINECS No : 2311329 Main Material : Tellurium (Te) Molecular Formula : Te Standard : Meets analytical and research standard requirements Melting Point : 449.5C Other Names : Te nanowire, Tellurium nanorods Molecular Weight : 127.60 g/mol Grade : Other, High purity, research grade Type : Nanowire Classification : Other, Elemental nanomaterial Density : 6.24 Gram per cubic centimeter(g/cm3) Poisonous : Yes Boiling point : 990C Application : Other, Semiconductor devices, solar cells, photodetectors, thermoelectric materials, nanotechnology research Purity : 99.99% Shape : Other, Wireshaped nano structure Ph Level : Neutral (7) Form : Other, Powder or dispersed in solution Solubility : Insoluble in water, soluble in concentrated acids and alkalis Smell : Other, Odorless CAS No : 13494809 Storage : Other, Store in a cool, dry, and wellventilated place away from heat sources and oxidizing agents HS Code : 28049090 Usage : Applied in electronic components, energy conversion, chemical sensors, and nanomaterials Taste : Other , Tasteless

Send Inquiry

Copper Hydroxide Nanowires Structural Formula : Cu(OH)2 Chemical Name : Copper(II) Hydroxide EINECS No : 2151373 Main Material : Copper Hydroxide (Cu(OH)2) Molecular Formula : Cu(OH)2 Standard : Meets industrial/analytical standards Melting Point : Decomposes before melting Other Names : Cupric Hydroxide Nanowires Molecular Weight : 97.56 g/mol Grade : Other, Analytical Grade, Industrial Grade, Nano Grade Type : Nanowires Classification : Other, Inorganic Compounds, Nanomaterials Density : 3.368 Gram per cubic centimeter(g/cm3) Poisonous : Yes Boiling point : Not applicable (decomposes on heating) Application : Other, Catalysis, antimicrobial agent, battery electrode, sensor devices, nanoinks, advanced materials, electronics Purity : 99% Shape : Other, Rodlike nanowire Ph Level : Alkaline Form : Other, Solid, powder or wire form Solubility : Insoluble in water, soluble in ammonia and acids Smell : Other, Odorless CAS No : 20427592 Storage : Other, Store in a cool, dry place, in sealed container, away from light HS Code : 28254000 Usage : Research, industrial, chemical synthesis, laboratory use Taste : Other , Tasteless

Send Inquiry

Nickel Hydroxide Nanowire Structural Formula : [Ni(OH)2] Chemical Name : Nickel Hydroxide EINECS No : 2152333 Main Material : Nickel Hydroxide Molecular Formula : Ni(OH)2 Standard : Complies with industrial and laboratory standards Melting Point : Decomposes before melting Other Names : Ni(OH)2, Nickel(II) hydroxide Molecular Weight : 92.71 g/mol Grade : Other, Analytical/Reagent Grade Type : Nanowire Classification : Other, Inorganic compound Density : 4.15 Gram per cubic centimeter(g/cm3) Poisonous : Yes Boiling point : Not applicable (decomposes) Application : Other, Battery electrodes, catalysts, supercapacitors, sensors, electrochemical devices Purity : 99% or higher Shape : Other, Nanowire Ph Level : Alkaline Form : Other, Solid, powder or suspension Solubility : Insoluble in water Smell : Other, Odorless CAS No : 12054487 Storage : Other, Store in a cool, dry, ventilated place, away from incompatible substances HS Code : 28259040 Usage : Used in energy storage, chemical synthesis, and as an electrochemical material Taste : Odorless

Send Inquiry

Gold Nanowire Structural Formula : Au Chemical Name : Gold Nanowire EINECS No : 2311659 Main Material : Gold (Au) Molecular Formula : Au Standard : ASTM/ISO nanomaterial standards Melting Point : 1064C Other Names : Au Nanowire Molecular Weight : 196.97 g/mol Grade : Other, Laboratory/Reagent Grade Type : Metallic Nanowire Classification : Other, Nano Material Density : 19.32 Gram per cubic centimeter(g/cm3) Poisonous : Yes Boiling point : 2856C Application : Other, Electronics, Sensors, Catalysis, Biomedical Purity : 99.99% Shape : Other, Wire (Nanowire) Ph Level : Neutral (pH 7) Form : Solid Solubility : Insoluble in water, soluble in some organic solvents Smell : Other, Odorless CAS No : 7440575 Storage : Other, Store in a cool, dry place, away from acids/halides HS Code : 7108 Usage : Nanoelectronics, nanoscale devices, research

Send Inquiry

SEND INQUIRY CALL ME FREE