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Quantum Capacitance Effects In Carbon Nanotube Field-Effect Devices

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1 Quantum Capacitance Effects In Carbon Nanotube Field-Effect Devices
L. Latessa, A. Pecchia, A. Di Carlo University of Rome ‘Tor Vergata’ P. Lugli Lehrstuhl fur Nanoelectronic, Munchen

2 Devices based on field effect (CNTFET)
Planar geometry top/bottom gate (IBM) ULSI Devices Quasi-1D coherent transport over long distances Si integrable technology Vertical Geometry coaxial gate (Infineon)

3 gDFTB Green’s functions Density Functional Tight-Binding
(A.Pecchia, L.Latessa, A.Di Carlo) Atomistic simulations: Quantum treatment Approximated DFT:

4 A. Pecchia, A. Di Carlo, Rep Prog Phys 67, 1-65 (2004)
NEGF Extention L R Density Matrix Mullikan Charges SCC loop A. Pecchia, A. Di Carlo, Rep Prog Phys 67, 1-65 (2004)

5 3D Poisson Multigrid The cylindrical gate is added as an
appropiate Dirichlet boundary condition Metal Gate Insulating dielectric and CNT

6 Coaxially gated CNTFET
Working mechanisms: Schottky barrier modulation at the contacts local modulation of channel conductance Model: semiconducting CNT(10,0) neglect Schottky barrier Charge injection from p-doped CNT contacts

7 CNTFET control capacities
Cox CQ Vg VCNT CS CG CG CD (S.Luryi, Appl.Phys.Lett. 52, 501 (1988), sistemi 2DES)

8 Gate capacitance Gate is a Macroscopic metal
Oxide CNT In a classic MOS CQ >> Cox => modulation depends on Cox In a well-tempered MOS CG >> CS,CD In 1D systems CQ is small Vds can influence the channel charge and barrier

9 Caratteristiche di uscita IDS/VDS
Source Drain Source Drain

10 Calculation of CQ Bare Potential Partial Screening

11 Over-screening in CNT Negative CQ Ctot > Cins
The can CNT better than a metal!

12 Negative compressibility
Experimental measurements in GaAs quantum wells J.P.Eisenstein et al., Phys.Rev.Lett. 68, 647 (1992)  Analytic results for quasi-1D electron systems L.Calmels, A.Gold, Phys. Rev.B. 53, (1996) K0 : free electrons compressibility KHFA: Hartree-Fock exchange compress.

13 Many-body exchange effect
Calcolo DFT Charge carrier density nC: TOTAL SCREENING CNT ~ macroscopico CQ= e2(EF) High density: PARTIAL SCREENING Dominated by DOS Low density: OVER-SCREENING Exchange interaction preveal

14 XC in gDFTB In DFTB the XC term is treated with a Hubbard on-site energy Substituting UH with Uee accounts only for Hartree rs=5.03 rs=6.71 rs=10.06 rs=20.12 The capacity becomes positive again

15 Quantum Capacitance vs DOS

16 Over-screening and modulation
VGS Unconventional Trans-characteristics Possible applications ? VGS

17 Conclusions Comprehensive calculation of Quantum Capacity in a CNT(10,0) using NEGF XC effects can give deviations from “classical” CQ Negative CQ below a crytical carrier density which compares well with analytic results in quasi 1D systems More complicated behaviour when more subbands are occupied

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