Laboratorio MDM, CNR-IMM, Via Olivetti 2, I-20864 Agrate Brianza, Italy.
Nanotechnology. 2012 Jun 1;23(21):215204. doi: 10.1088/0957-4484/23/21/215204.
We report the electronic transport on n-type silicon single electron transistors (SETs) fabricated in complementary metal oxide semiconductor (CMOS) technology. The n-type metal oxide silicon SETs (n-MOSSETs) are built within a pre-industrial fully depleted silicon on insulator (FDSOI) technology with a silicon thickness down to 10 nm on 200 mm wafers. The nominal channel size of 20 × 20 nm(2) is obtained by employing electron beam lithography for active and gate level patterning. The Coulomb blockade stability diagram is precisely resolved at 4.2 K and it exhibits large addition energies of tens of meV. The confinement of the electrons in the quantum dot has been modeled by using a current spin density functional theory (CS-DFT) method. CMOS technology enables massive production of SETs for ultimate nanoelectronic and quantum variable based devices.
我们报告了在互补金属氧化物半导体 (CMOS) 技术中制造的 n 型硅单电子晶体管 (SET) 的电子输运特性。n 型金属氧化物硅 SET (n-MOSSET) 是在预工业全耗尽硅绝缘体 (FDSOI) 技术中构建的,其硅厚度低至 10nm,晶圆直径为 200mm。通过使用电子束光刻对有源区和栅极进行图案化,获得了 20×20nm(2)的名义沟道尺寸。在 4.2K 下精确解析库仑阻塞稳定性图,并表现出数十毫电子伏特的大附加能量。通过电流自旋密度泛函理论 (CS-DFT) 方法对量子点中的电子限制进行了建模。CMOS 技术使 SET 的大规模生产成为可能,从而实现了基于纳米电子和量子变量的最终设备。