TADF Dopant Materials

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TADF dopant materials are organic molecules that efficiently convert triplet excitons into light by using small amounts of heat, enabling nearly 100% internal quantum efficiency without heavy metals. TADF dopants feature distinct donor-acceptor structures that facilitate a process called reverse intersystem crossing (RISC), allowing triplet energy to become singlet energy and emit light, a key breakthrough for high-performance displays

The donor-acceptor structure can create a small energy gap between singlet and triplet excited states, allowing triplet excitons to be thermally activated back to the singlet state to achieve near 100% internal quantum efficiency, rivalling phosphorescent materials, especially crucial for blue light.

TADF dopant materials include blue, green, yellow, orange, and red TADF emitters, and also high color purity MR-TADF emitters.

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Red Dopant Materials

Browse our high purity red emitters.

Yellow Dopant Materials

Explore our high purity yellow emitters.

Green Dopant Materials

Browse our high purity green emitters.

Blue Dopant Materials

View our high purity blue emitters.

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4CzPN-Ph

CAS 1469707-47-8

From $315

4CzPN-Me

CAS 1469700-28-4

From $315

4CzIPN-tBu

CAS 1630263-99-8

From $315

4CzIPN-Ph

CAS 1469705-37-0

From $315

4CzIPN-Me

CAS 1469703-61-4

From $315

4CzFCN

CAS 1819362-10-1

From $285

4CzBN

CAS 1996609-93-8

From $255

3tPAB

CAS 2056877-25-7

From $435

3DPA-DiKTa

From $1,005

3CzBN

CAS 1799923-03-7

From $240

2PTZBN

CAS 2250280-17-0

From $375

Fluorescence and Phosphorescence

Fluorescence and phosphorescence are types of photoluminescence. Photoluminescence refers to radiative emissions where the absorbance of a photon is followed by the emission of a lower energy photon. The main empirical difference between fluorescence and phosphorescence is the time in between absorbance and the emission of photons. Fluorescence is where a material absorbs a photon, and almost immediately emits a lower energy photon.

Organic Light Emitting Diodes

Organic light emitting diodes are thin film devices that convert electrical energy into visible light. In OLED devices, electrons and holes are injected into the organic medium and recombine radiatively via electroluminescence (EL). The color of the light emitted is dependent on the molecular structure of the organic material. This can be easily customized to make a wide range of wavelengths thanks to the endless configurations of organic molecules.

OLED Fabrication Guide

In this guide, we demonstrate how to make standard OLED devices in a glove box using materials and equipment easily available to any lab. Find out more.

OLED Testing Guide

This guide gives you an overview of what to consider when characterizing an OLED, as well as tips for their measurement.