COMPATIBILITY METHODS

✓ Cyclic Voltammetry (CV)
✓ Chronoamperometry (CA)
✓ Square Wave Voltammetry (SWV)
✓ Differential Pulse Voltammetry (DPV)
✓ Open Circuit Potentiometry (OCP)
✓ Electrochemical Impedance Spectroscopy (EIS)

TECHNICAL DATASHEET

Product Name: Silver Screen Printed Electrode (3-Electrode System)
Model: SPE-C/Ag/CE-3E

The SPE-C/Ag/CE-3E is a high-performance, disposable screen-printed electrode designed for research, environmental monitoring, and healthcare diagnostics.

Its optimized geometry ensures high reproducibility, while the standard connector enables seamless integration with major electrochemical workstations.

PERFORMANCE CHARACTERISTICS

Test Solution: 2.5 mM Ferricyanide in 0.1 M KCl

• Reversible redox peak observed (Ep ≈ 70–80 mV)
• Stable baseline with low background current
• Reproducibility: < 5% RSD between electrodes (n = 20)
• Application validated for:
– Heavy metal detection (Pb²⁺, Cd²⁺)
– Glucose detection
– Ascorbic acid analysis
– DNA hybridization studies

TECHNICAL SPECIFICATION

Parameter	Specification
Electrode Type	Screen-Printed Silver Electrode
Configuration	3-Electrode System (Working, Counter, Reference)
Material	Silver-based conductive ink
Sample Volume Required	≤ 50 µL
Storage Condition	Ambient storage
Connector Type	Standard electrochemical workstation compatible
Shelf Life	Long shelf life under proper storage conditions

APPLICATIONS

Environmental Monitoring:
• Heavy metal detection
• Pesticide analysis
• Water quality testing

Healthcare Diagnostics:
• Glucose detection
• Lactate monitoring
• DNA and biomarker detection

Food Safety:
• Adulterant detection
• Freshness monitoring

Education & Research:
• Electrochemical teaching kits
• Laboratory research applications

COMPLIANCE & QUALITY

• Manufactured under ISO 9001:2015 certification
• RoHS compliant
• REACH compliant
• Each batch tested using 2.5 mM ferricyanide QC protocol

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Printed electronics is reshaping the electronics industry by introducing forward-thinking methods for designing and manufacturing electronic components. Utilizing advanced printing technologies, such as screen printing and flexographic printing, functional inks with conductive, semiconductive, and insulating properties are accurately deposited onto flexible or rigid substrates, including plastic, paper, and glass. This technique enables the development of lightweight, cost-effective, and versatile electronic solutions, perfectly suited to the growing demand for sustainable and flexible technologies. A hallmark of printed electronics is its capability to fabricate ultra-thin, flexible, and stretchable circuits. These features make it highly adaptable for a wide array of applications, such as wearable devices, smart clothing, bendable displays, and advanced medical sensors. Moreover, the roll-to-roll manufacturing process supports large-scale, continuous production, significantly cutting costs and reducing environmental impact compared to traditional electronic fabrication methods. This transformative technology brings intelligence into everyday objects, enabling innovations like RFID tags for efficient supply chain management, interactive smart packaging, and energy-harvesting devices like flexible solar cells. It has also been embraced for the development of touch-responsive interfaces and smart lighting systems, enhancing user interactivity and design possibilities. In the healthcare domain, printed electronics have led to the development of disposable biosensors and wearable health-monitoring devices, supporting real-time diagnostics and patient care. It has also played a pivotal role in accelerating the Internet of Things (IoT) by facilitating the deployment of low-cost, high-performance sensors across a variety of applications. Printed electronics represents the intersection of efficiency, flexibility, and cutting-edge innovation. It is emerging as a key enabler of sustainable manufacturing and next-generation product development. By integrating printed electronics, industries gain access to new possibilities, revolutionizing the way technology is embedded into daily life and enhancing the functionality of everyday products.

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