Evolution of high performance microprocessors has resulted in a steady decrease in on-chip feature sizes. Increasing requirements on maximum current density are expected to increase interconnect temperature drastically due to Joule heating. As interconnect dimensions approach the electron mean free path range, effective conductivity reduces due to size effects. Thermal characterization of sub-micron interconnects and thin films is thus highly important. This work investigates current crowding and the associated Joule heating near a constriction in a thin metallic film and proposes a novel technique to determine thermal conductivity of thin metallic films and interconnects in the sub-100 nm range. Scanning Joule Expansion Microscopy (SJEM) measures the thermal expansion of the structure whose thickness is comparable to the mean free path of electrons. Numerical solution of heat conduction equation in the frequency space is used to obtain a fit for effective thermal conductivity. A thermal conductivity of ~ 80.0 W/mK provides a best fit to the data. This is about one-third the bulk thermal conductivity of gold, which is 318 W/mK at room temperature. Using Wiedemann-Franz Law a thermal conductivity of 92.0 W/mK is obtained after measuring the electrical resistivity of the metal line. This is close to that obtained through numerical fit.

Volume Subject Area:
Heat Transfer
Topics:
Heating, Joules, Metallic thin films, Nanoscale phenomena, Thermal conductivity, Electrons, Mean free path, Metallic films, Temperature, Current density, Dimensions, Electrical resistivity, Heat conduction, Metals, Microscopy, Thermal characterization, Thermal expansion, Thin films, Wiedemann-Franz law
1.
Banerjee, K., Mehrotra, A., Hunter, W., Saraswat, K. C., Goodson, K. E., and Wong, S. S., 2000, “Quantitative Projections of Reliability and Performance for Low-k/Cu Interconnect Systems,” Proc. of the 38th IEEE Annual International Reliability Physics Symposium (IRPS), San Jose, CA, pp. 354–358.
2.
Streiter
R.
,
Wolf
H.
,
Zhu
Z.
,
Xiao
X.
, and
Gessner
T.
,
2002
, “
Application of Combined Thermal and Electrical Simulation for Optimization of Deep Submicron Interconnection Systems
,”
Microelectronic Engineering
, Vol.
60
, pp.
39
49
.
3.
Varesi
J.
, and
Majumdar
A.
,
1998
, “
Scanning Joule Expansion Microscopy at Nanometer Scales
,”
Applied Physics Letters
, Vol.
72
, pp.
37
39
.
4.
Nath
P.
, and
Chopra
K. L.
,
1973
, “
Experimental Determination of the Thermal Conductivity of Thin Films
,”
Thin Solid Films
, Vol.
18
, pp.
29
37
.
5.
Hatta
I.
,
Sasuga
Y.
,
Kato
R.
, and
Maesono
A.
,
1985
, “
Thermal Diffusivity Measurement of Thin Films by Means of an AC Calorimetric Method
,”
Review of Scientific Instruments
, Vol.
56
, pp.
1643
1647
.
6.
Yamane
T.
,
Mori
Y.
,
Katayama
S.-I.
, and
Todoki
M.
,
1997
, “
Measurement of Thermal Diffusivities of Thin Metallic Films Using the AC calorimetric Method
,”
Journal of Applied Physics
, Vol.
82
, pp.
1153
56
.
7.
Langer
G.
,
Hartmann
J.
, and
Reichling
M.
,
1997
, “
Thermal Conductivity of Thin Metallic Films Measured by Photothermal Profile Analysis
,”
Review of Scientific Instruments
, Vol.
68
, pp.
1510
13
.
8.
Wang
X.
,
Hu
H.
, and
Xu
X.
,
2001
, “
Photo-Acoustic Measurement of Thermal Conductivity of Thin Films and Bulk Materials
,”
ASME Journal of Heat Transfer
, Vol.
123
, pp.
138
44
.
9.
Cahill
D. G.
,
1990
, “
Thermal Conductivity Measurement from 30-K to 750-K — The 3w Method
,”
Review of Scientific Instruments
, Vol.
61
, pp.
802
808
.
10.
Ashcroft, N. W., and Mermin, N. D., 1976, Solid State Physics, Rinehart and Winston, New York.
This content is only available via PDF.
Copyright © 2005
 by ASME
You do not currently have access to this content.