Electrical Characteriza-on and Test
Pull-‐In/Pull-‐Out Voltage
Measuring Actua-on Delay
Pull-‐in/Pull-‐out Voltage
Reliability Tes-ng
MOCVD TiN-‐Coated Polysilicon
Procedure: 1. Bias drain and ground source (beam) 2. Increase the applied gate voltage
(quasi-‐sta=c ramp) un=l drain current increases sharply, indica=ng pull-‐in.
3. Ramp gate voltage back down to zero. Pull-‐out occurs when drain current drops below noise floor.
All tes'ng is performed in a controlled N2 glovebox probe sta'on to protect samples against degrada'on due to ambient moisture.
Procedure: 1. Apply a square pulse of magnitude >VPI to the gate.
*Variable parameters: rise/fall sharpness, pulse width
2. Possible outcomes a) If device fails, drain voltage VD remains at zero. b) If device actuates, drain voltage VD approaches
the source bias VS. The resul=ng plot allows us to calculate mechanical delay, actua=on =me, and contact resistance.
Time (s)
Gate/Drain Voltage (V)
Mechanical Delay
Pull-In Voltage (VPI)
100
200
0
300
600
500
400
Mechanical Delay (ns)
Ini-alize
Apply gate pulse
Did switching occur?
Pulse N -mes End test
Yes No
Image Credit: Soogine Chong (Reliability tes=ng)
-‐5
0
5
10
15
20
25
0 10 20 30 40 50
Drain Current (n
A)
Gate Voltage (V)
Hysteresis
Pull-‐in
Pull-‐out
Joel Jean [email protected]
Srikanth Iyer [email protected]
MOSFET-‐Killer: Nanoelectromechanical (NEM) Relays for Low-‐Power Logic Joel Jean, Srikanth Iyer, W. ScoT Lee, Roger Howe
Abstract To con=nue the trend of increasingly powerful, smaller, and cheaper consumer electronic
devices and to keep up with the self-‐fulfilling prophecy of Moore’s Law, silicon-‐based metal-‐oxide-‐semiconductor field effect transistors (MOSFETs) have been con=nually scaled down in size for the last several decades. The advantages of scaling are many: Smaller devices consume less power, have improved current drive and frequency response, and enable increased device packing density, resul=ng in lower fabrica=on cost per chip. In decreasing the dimensions of MOSFETs, however, we find that transistor leakage currents––from gate oxide tunneling, drain-‐induced barrier lowering (DIBL), and band-‐to-‐band tunneling (BTBT)––correspond to an increasingly large propor=on of the total power consump=on. The MOSFET’s fundamentally-‐limited subthreshold slope precludes low-‐power logic based on exis=ng CMOS technologies.
In the current research, we explore nanoelectromechanical (NEM) relays as a poten=al replacement for MOSFETs in low-‐power applica=ons, such as mobile devices and sensors, and as sleep transistors in both FPGAs and ASICs. We have performed electrical characteriza=on, iden=fied common failure mechanisms, and conducted dynamic (switching =me and pulse) measurements of a variety of microfabricated NEM relay structures in a nitrogen glovebox test environment. Our future work will involve inves=ga=on of energy recovery (ER) techniques for lowering dynamic power consump=on, durability tes=ng, and implementa=on of logic func=ons. Ul=mately, the near-‐ideal switching behavior of electrosta=cally actuated NEM relays––negligible off-‐current and near-‐infinite subthreshold slope––and compa=bility with exis=ng CMOS fabrica=on technologies offer a promising route to longer baTery life and increased performance in tomorrow’s consumer electronics.
Failure Mechanisms
S-c-on
Pull-‐In to Gate
Beam Curling Explosion
When the beam is too flexible, it may touch the gate before pulling into the drain. At high poten=als, this contact can destroy fragile beams.
ATrac=ve surface forces (i.e., van der Waals) dominate at close range: Acer actua=on, adhesive force between the beam and drain some=mes exceeds the mechanical restoring force of the beam, and the beam fails to pull out. S=c=on is exacerbated by overdriving the gate pulse and passing high current through the beam and drain.
Relay Design and Opera-on
Device Layout and Fabrica-on
Electrosta-c Actua-on
Drain
Beam
+ – VGS
Gate Source
Beam
Gate 1 Gate 2
Drain 1 Drain 2
g b
s
d o
w
MOCVD TiN Stringer
TiN Sidewall Stringer
Image Credit: Roozbeh Parsa (Electrosta=c schema=c), Kyeongran Yoo (5T device parameters)
Future Work & Applica-ons
FPGA Rou-ng Switches
Energy Recovery (ER) Tes-ng
In applica=ons where the device alternates between lec and right actua=on, we can use a 5-‐terminal relay to reduce dynamic power consump=on by taking advantage of the restoring momentum of the beam. While the beam is pulling out from one side, the pull-‐in voltage on the other side is effec=vely decreased.
Image Credit: Chen Chen (FPGA data)
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