Particle Metrology

with shape classification in real-time

The Q.ANT Par­ti­cle Sensor fami­ly enab­les par­ti­cle sen­sing and ana­ly­sis in real-time for direct con­trol of your pro­ces­ses. Next to the size dis­tri­bu­ti­on of the par­ti­cles, an arti­fi­cial intel­li­gence (AI) ana­ly­zes the mea­su­red para­me­ters and clas­si­fies the par­ti­cles accord­ing to shape. This enab­les opti­mi­zed and sus­tainab­le ope­ra­ti­ons in a wide ran­ge of applications.

Waveguides

for the control of light and quantum effects in a highly integrated form

Wave­gui­des are the cen­tral buil­ding block of opti­cal data pro­ces­sing. In addi­ti­on to app­li­ca­ti­ons in telecom­mu­ni­ca­ti­on, this technology is at the heart of a wide ran­ge of quantum technology app­li­ca­ti­ons, from quantum sen­sing and quantum com­mu­ni­ca­ti­on to quantum com­pu­ting. Our goal is to deve­lop a ful­ly func­tio­n­al quantum chip that will sup­port today’s computers.

Quantum Computing

Q.ANT is pro­ject part­ner and con­sor­ti­um lea­der in the BMBF-fun­ded pro­ject Pho­Quant (Press release) for the development of a pho­to­nic quantum computer.

Nuclear spin-based quantum gyroscopes

for new space applications

Q.ANT is pro­ject part­ner and con­sor­ti­um lea­der for the QYRO pro­ject (Press release), which is fun­ded by the BMBF. QYRO aims to deve­lop a space-qua­li­fied and high­ly accu­ra­te angu­lar rate sensor based on the quantum effect of nuclear magne­tic reso­nance, which can be used to pre­cise­ly con­trol the satel­li­te atti­tu­de wit­hin a satel­li­te net­work for Inter­net communication.