001021432 001__ 1021432
001021432 005__ 20250129092403.0
001021432 037__ $$aFZJ-2024-00729
001021432 1001_ $$0P:(DE-Juel1)180854$$aSchreckenberg, Lea$$b0$$eCorresponding author$$ufzj
001021432 1112_ $$aESSCIRC 2023- IEEE 49th European Solid State Circuits Conference (ESSCIRC)$$cLisbon$$d2023-09-11 - 2023-09-14$$wPortugal
001021432 245__ $$aSiGe Qubit Biasing with a Cryogenic CMOS DAC at mK Temperature
001021432 260__ $$c2023
001021432 3367_ $$033$$2EndNote$$aConference Paper
001021432 3367_ $$2DataCite$$aOther
001021432 3367_ $$2BibTeX$$aINPROCEEDINGS
001021432 3367_ $$2DRIVER$$aconferenceObject
001021432 3367_ $$2ORCID$$aLECTURE_SPEECH
001021432 3367_ $$0PUB:(DE-HGF)6$$2PUB:(DE-HGF)$$aConference Presentation$$bconf$$mconf$$s1705664744_18115$$xAfter Call
001021432 500__ $$aCorresponding Journal Paper: https://juser.fz-juelich.de/record/1018304
001021432 520__ $$aFor running advanced algorithms on a universal quantum computer, millions of qubits are required. To make use of quantum effects, state-of-the-art solid-state qubit devices have to be cooled to mK temperatures, which limits the systems’ scalability with room temperature (RT) electronics. We present the direct co-integration of a scalable, fully integrated, eight channel Bias-DAC designed in a 65-nm bulk CMOS technology and a Si/SiGe spin qubit device at the mixing chamber (MC) of a dilution refrigerator operating below 45 mK MC temperature. As a full proof of principle, the bias of a single electron transistor used as a sensing dot, as well as a single and double quantum dot bias of the qubit device is reported. The slow drift of the DAC S&H output circuit of 0.96 μV/s leads to a calculated prospective power consumption of 64.5 pW/ch for DC qubit bias voltages generated at low temperature
001021432 536__ $$0G:(DE-HGF)POF4-5223$$a5223 - Quantum-Computer Control Systems and Cryoelectronics (POF4-522)$$cPOF4-522$$fPOF IV$$x0
001021432 536__ $$0G:(DE-HGF)POF4-5221$$a5221 - Advanced Solid-State Qubits and Qubit Systems (POF4-522)$$cPOF4-522$$fPOF IV$$x1
001021432 7001_ $$0P:(DE-Juel1)174088$$aOtten, Rene$$b1$$ufzj
001021432 7001_ $$0P:(DE-Juel1)171680$$aVliex, Patrick$$b2$$ufzj
001021432 7001_ $$0P:(DE-Juel1)186616$$aXue, Ran$$b3
001021432 7001_ $$0P:(DE-Juel1)167206$$aTu, Jhih-Sian$$b4$$ufzj
001021432 7001_ $$0P:(DE-HGF)0$$aSeidler, Inga$$b5
001021432 7001_ $$0P:(DE-Juel1)128856$$aTrellenkamp, Stefan$$b6$$ufzj
001021432 7001_ $$0P:(DE-Juel1)172641$$aSchreiber, Lars$$b7$$ufzj
001021432 7001_ $$0P:(DE-Juel1)172019$$aBluhm, Hendrik$$b8$$ufzj
001021432 7001_ $$0P:(DE-Juel1)142562$$avan Waasen, Stefan$$b9$$ufzj
001021432 909CO $$ooai:juser.fz-juelich.de:1021432$$pVDB
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001021432 9101_ $$0I:(DE-588b)5008462-8$$6P:(DE-Juel1)167206$$aForschungszentrum Jülich$$b4$$kFZJ
001021432 9101_ $$0I:(DE-588b)5008462-8$$6P:(DE-Juel1)128856$$aForschungszentrum Jülich$$b6$$kFZJ
001021432 9101_ $$0I:(DE-588b)5008462-8$$6P:(DE-Juel1)172641$$aForschungszentrum Jülich$$b7$$kFZJ
001021432 9101_ $$0I:(DE-588b)5008462-8$$6P:(DE-Juel1)172019$$aForschungszentrum Jülich$$b8$$kFZJ
001021432 9101_ $$0I:(DE-588b)5008462-8$$6P:(DE-Juel1)142562$$aForschungszentrum Jülich$$b9$$kFZJ
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001021432 9131_ $$0G:(DE-HGF)POF4-522$$1G:(DE-HGF)POF4-520$$2G:(DE-HGF)POF4-500$$3G:(DE-HGF)POF4$$4G:(DE-HGF)POF$$9G:(DE-HGF)POF4-5221$$aDE-HGF$$bKey Technologies$$lNatural, Artificial and Cognitive Information Processing$$vQuantum Computing$$x1
001021432 9141_ $$y2023
001021432 920__ $$lyes
001021432 9201_ $$0I:(DE-Juel1)ZEA-2-20090406$$kZEA-2$$lZentralinstitut für Elektronik$$x0
001021432 9201_ $$0I:(DE-Juel1)PGI-11-20170113$$kPGI-11$$lJARA Institut Quanteninformation$$x1
001021432 9201_ $$0I:(DE-Juel1)HNF-20170116$$kHNF$$lHelmholtz - Nanofacility$$x2
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001021432 980__ $$aVDB
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001021432 980__ $$aI:(DE-Juel1)PGI-11-20170113
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001021432 981__ $$aI:(DE-Juel1)PGI-4-20110106