Despite the recent introduction of heavily-doped semiconductors for mid-infrared plasmonics, it still remains an open point whether such materials can compete with noble metals. We employ a whole set of figures of merit to thoroughly assess the use of heavily-doped Ge on Si as a mid-infrared plasmonic material and benchmark it against standard noble metals such as Au. In doing this, we design and model high-performance, CMOS compatible mid-infrared plasmonic sensors based on experimental material data reaching plasma frequencies up to about 1950 cm−1. We demonstrate that plasmonic Ge sensors can provide signal enhancements for vibrational spectroscopy above 3 orders of magnitude, thus representing a viable alternative to noble metals

Baldassarre, Leonetta

Biagioni, Paolo

Frigerio, Jacopo

Gallacher, Kevin

Giliberti, Valeria

Isella, Giovanni

Ortolani, Michele

Paul, Douglas J.

Pellegrini, Giovanni

English

Despite the recent introduction of heavily-doped semiconductors for mid-infrared plasmonics, it still remains an open point whether such materials can compete with noble metals. We employ a whole set of figures of merit to thoroughly assess the use of heavily-doped Ge on Si as a mid-infrared plasmonic material and benchmark it against standard noble metals such as Au. In doing this, we design and model high-performance, CMOS compatible mid-infrared plasmonic sensors based on experimental material data reaching plasma frequencies up to about 1950 cm-1. We demonstrate that plasmonic Ge sensors can provide signal enhancements for vibrational spectroscopy above 3 orders of magnitude, thus representing a viable alternative to noble metals

Archivio della ricerca- Università di Roma La Sapienza

Benchmarking the use of heavily-doped Ge against noble metals for plasmonics and sensing in the mid-infrared

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     Pellegrini, G., Baldassarre, L., Giliberti, V., Frigerio, J., Gallacher, K., Paul, D. J., Isella, G., Ortolani, M., and Biagioni, P. (2016) Benchmarking the Use of Heavily-Doped Ge Against Noble Metals for Plasmonics and Sensing in the Mid-Infrared. In: 41st International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2016), Copenhagen, Denmark, 25-30 Sept 2016, ISBN 9781467384858 (doi:10.1109/IRMMW-THz.2016.7758628)  This is the author’s final accepted version.  There may be differences between this version and the published version. You are advised to consult the publisher’s version if you wish to cite from it.     http://eprints.gla.ac.uk/132476/            Deposited on: 07 December 2016                      Enlighten – Research publications by members of the University of Glasgow http://eprints.gla.ac.uk  Abstract—Despite the recent introduction of heavily-doped semiconductors for mid-infrared plasmonics, it still remains an open point whether such materials can compete with noble metals. We employ a whole set of figures of merit to thoroughly assess the use of heavily-doped Ge on Si as a mid-infrared plasmonic material and benchmark it against standard noble metals such as Au. In doing this, we design and model high-performance, CMOS compatible mid-infrared plasmonic sensors based on experimental material data reaching plasma frequencies up to about 1950 cm-1. We demonstrate that plasmonic Ge sensors can provide signal enhancements for vibrational spectroscopy above 3 orders of magnitude, thus representing a viable alternative to noble metals. I. INTRODUCTION HE  direct targeting of the molecule vibrational fingerprints demands for new enhanced sensors operating in the mid-infrared (mid-IR) range. In this framework, plasmonic devices have been proposed as a way to achieve increased light-molecule interaction leading to the so-called surface-enhanced infrared absorption (SEIRA) spectroscopy. Even though most research efforts focused their attention on gold platforms so far, heavily-doped semiconductors have recently demonstrated their potential as fabrication materials for mid-IR sensing devices [1]. The most relevant advantages include the high material quality obtained with the epitaxial growth and the potential for on-chip CMOS integration of group-IV semiconductors. Yet, in order to obtain high-performance sensing platforms, it is crucial to reach an accurate characterization of the plasmonic properties of the material and achieve a sensor design capable of providing high local field enhancements over large and uniform areas. II. RESULTS We design and model, by means of a multilayer finite-element method, free-standing nano-slit arrays based on heavily-doped Ge epitaxially grown on Si. Such devices are well within the capabilities of modern fabrication technologies developed for semiconductor membranes on silicon chips. The plasmonic properties of the Ge can be evaluated in terms of field confinement and propagation length [2]. In this context, Ge compares favorably to other semiconductors and demonstrates mid-IR enhancement properties within one order of magnitude of those typically displayed by noble metals in the visible range. Moreover, we exploit a set of three different figures of merit to capture all the different aspects of plasmonic enhancement under realistic experimental conditions. The metrics are defined as a function of two quantities determined in a far field reflection geometry, and represent an improvement on different approaches based on local field quantities that are biased towards large area coverages in spite of large signal enhancements. The first introduced quantity is defined as ??????? and corresponds to the baseline-corrected SEIRA signal of a volume ?????? of target molecules interacting with the plasmonic platform. The second quantity ?????? coincides with the vibrational signal arising from the same volume of molecule ?????? deposited on a bare substrate [Fig. 1]. In this framework the first introduced figure of merit is simply defined as ?????? ? ???????. The metric serves as a proxy of the measured signal intensity, allowing for the monitoring of the platform signal-to-noise ratio, which can be approximately expressed as ??? ? ????????????. The second proposed metric is defined as the ratio of the baseline-corrected SEIRA signal amplitude to the one of the bare target molecules, i.e. ???????? ? ??????????????. The metric monitors the SEIRA enhancement performance and is solely related to the intrinsic signal enhancement properties of the sensing device. The last  Giovanni Pellegrini1, Leonetta Baldassarre2,3, Valeria Giliberti2,3, Jacopo Frigerio4, Kevin Gallacher5, Douglas J. Paul5, Giovanni Isella4, Michele Ortolani2, and Paolo Biagioni1 1Dipartimento di Fisica, Politecnico di Milano, I-20133 Milan, Italy 2 Dipartimento di Fisica, Sapienza Università di Roma, I-00185 Rome, Italy  3Center for Life Nano Sciences, Istituto Italiano di Tecnologia, I-00185 Rome, Italy 4L-NESS, Dipartimento di Fisica del Politecnico di Milano, I-22100 Como, Italy 5School of Engineering, University of Glasgow, Glasgow, G12 8LT, U.K. Benchmarking the use of heavily-doped Ge against noble metals for plasmonics and sensing in the mid-infrared  T Fig. 1. Schematic representation of nanoantenna and nanoslit SEIRA sensing platform and corresponding baseline corrected reflectance SEIRA signal(?RSEIRA), along with the reference reflectance signal for the same volume VSEIRA of target molecules deposited on the bare substrate (?Rbare). ??????????????????????????? ????? ????devised metric aims at the description of the measured SEIRA signal under realistic experimental conditions. In a typical experiment, a volume ???? ? ?????? ? ????? of analyte is usually delivered to the sensing platform and a reference substrate, where for the sensing device only a limited volume (??????) of the target molecules interacts with the plasmonic nanostructure, while the remaining volume fraction (?????) experiences no significant signal enhancement. In order to track the signal enhancement between the sensing platform and the reference substrate, starting from the quantities ??????? and ??????, it is then necessary to consider a normalization coefficient including  the relative volume fraction of sensitized molecules, finally obtaining:   ?????? ? ?????????????? ? ? ???????????? ?? As a practical example, we model and compare the performance of Au-based, state-of-the-art SEIRA platforms [3] against the newly-designed Ge-based sensing devices. We demonstrate that the adopted Ge nano-slit design allows for SEIRA signal enhancements, tracked by means of the ???????? metric, above 3 orders of magnitude in the 400-1000 cm-1 energy range [Fig. 2(a)], with uniform field enhancement inside the nano-slits. The signal enhancement compares favorably with the 3 to 4 orders of magnitude gain typically obtained with best performing Au-based platforms characterized by comparable geometrical parameters [Fig. 2(b)]. This indicates that plasmonic Ge sensors represent a viable alternative to noble metals for integrated plasmon enhanced vibrational spectroscopy in the mid-infrared range.  The research leading to these results has received funding from the European Union’s Seventh Framework Programme under grant agreement no. 613055.  REFERENCES [1] L. Baldassarre, E. Sakat, J. Frigerio, A. Samarelli, K. Gallacher, E. Calandrini, G. Isella, D. J. Paul, M. Ortolani, and P. Biagioni, “Midinfrared Plasmon-Enhanced Spectroscopy with Germanium Antennas on Silicon Substrates”, Nano Lett., vol. 15, pp. 7225–7231, Nov. 2015. [2] B. Dastmalchi, P. Tassin, T. Koschny, and C. M. Soukoulis, “A New Perspective on Plasmonics: Confinement and Propagation Length of Surface Plasmons for Different Materials and Geometries”, Advanced Optical Materials, vol. 4 pp. 177–184, Jan. 2016. [3] C. Huch, J. Vogt, M. Sendner, D. Hengstler, F. Neubrech, and A. Pucci, “Plasmonic Enhancement of Infrared Vibrational Signals: Nanoslits Versus Nanorods”, ACS Photonics, vol. 2 pp. 1489-1497, 2015 Fig. 2. (a) Local field enhancement and typical SEIRA signal for a Ge sensingplatform operating at 845 cm-1. (b) Local field enhancement and typical SEIRAsignal for a Au sensing platform operating at 3100 cm-1. 

Benchmarking the Use of Heavily-Doped Ge Against Noble Metals for Plasmonics and Sensing in the Mid-Infrared

Enlighten: Publications

 
 
 
 
 
Pellegrini, G., Baldassarre, L., Giliberti, V., Frigerio, J., Gallacher, K., Paul, 
D. J., Isella, G., Ortolani, M., and Biagioni, P. (2016) Benchmarking the 
Use of Heavily-Doped Ge Against Noble Metals for Plasmonics and 
Sensing in the Mid-Infrared. In: 41st International Conference on Infrared, 
Millimeter, and Terahertz Waves (IRMMW-THz 2016), Copenhagen, 
Denmark, 25-30 Sept 2016, ISBN 9781467384858 (doi:10.1109/IRMMW-
THz.2016.7758628) 
 
This is the author’s final accepted version. 
 
There may be differences between this version and the published version. 
You are advised to consult the publisher’s version if you wish to cite from 
it. 
 
 
 
 
http://eprints.gla.ac.uk/132476/ 
     
 
 
 
 
 
 
Deposited on: 07 December 2016 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Enlighten – Research publications by members of the University of Glasgow 
http://eprints.gla.ac.uk 
 
Abstract—Despite the recent introduction of heavily-doped 
semiconductors for mid-infrared plasmonics, it still remains an 
open point whether such materials can compete with noble metals. 
We employ a whole set of figures of merit to thoroughly assess the 
use of heavily-doped Ge on Si as a mid-infrared plasmonic 
material and benchmark it against standard noble metals such as 
Au. In doing this, we design and model high-performance, CMOS 
compatible mid-infrared plasmonic sensors based on experimental 
material data reaching plasma frequencies up to about 1950 cm-1. 
We demonstrate that plasmonic Ge sensors can provide signal 
enhancements for vibrational spectroscopy above 3 orders of 
magnitude, thus representing a viable alternative to noble metals. 
I. INTRODUCTION 
HE  direct targeting of the molecule vibrational fingerprints 
demands for new enhanced sensors operating in the mid-
infrared (mid-IR) range. In this framework, plasmonic 
devices have been proposed as a way to achieve increased light-
molecule interaction leading to the so-called surface-enhanced 
infrared absorption (SEIRA) spectroscopy. Even though most 
research efforts focused their attention on gold platforms so far, 
heavily-doped semiconductors have recently demonstrated 
their potential as fabrication materials for mid-IR sensing 
devices [1]. The most relevant advantages include the high 
material quality obtained with the epitaxial growth and the 
potential for on-chip CMOS integration of group-IV 
semiconductors. Yet, in order to obtain high-performance 
sensing platforms, it is crucial to reach an accurate 
characterization of the plasmonic properties of the material and 
achieve a sensor design capable of providing high local field 
enhancements over large and uniform areas. 
II. RESULTS 
We design and model, by means of a multilayer finite-element 
method, free-standing nano-slit arrays based on heavily-doped 
Ge epitaxially grown on Si. Such devices are well within the 
capabilities of modern fabrication technologies developed for 
semiconductor membranes on silicon chips. The plasmonic 
properties of the Ge can be evaluated in terms of field 
confinement and propagation length [2]. In this context, Ge 
compares favorably to other semiconductors and demonstrates 
mid-IR enhancement properties within one order of magnitude 
of those typically displayed by noble metals in the visible range. 
Moreover, we exploit a set of three different figures of merit to 
capture all the different aspects of plasmonic enhancement 
under realistic experimental conditions. The metrics are defined 
as a function of two quantities determined in a far field 
reflection geometry, and represent an improvement on different 
approaches based on local field quantities that are biased 
towards large area coverages in spite of large signal 
enhancements. The first introduced quantity is defined as 
߂ܴୗ୉୍ୖ୅ and corresponds to the baseline-corrected SEIRA 
signal of a volume ୗܸ୉୍ୖ୅ of target molecules interacting with 
the plasmonic platform. The second quantity ߂ܴୠୟ୰ୣ coincides 
with the vibrational signal arising from the same volume of 
molecule ୗܸ୉୍ୖ୅ deposited on a bare substrate [Fig. 1]. In this 
framework the first introduced figure of merit is simply defined 
as ୗ୒ୖ ൌ ߂ܴୗ୉୍ୖ୅. The metric serves as a proxy of the 
measured signal intensity, allowing for the monitoring of the 
platform signal-to-noise ratio, which can be approximately 
expressed as  ן ሺ߂ܴୗ୉୍ୖ୅ሻଵȀଶ. The second proposed metric 
is defined as the ratio of the baseline-corrected SEIRA signal 
amplitude to the one of the bare target molecules, i.e. 
ୗ୉୍ୖ୅ ൌ ߂ܴୗ୉୍ୖ୅Ȁ߂ܴୠୟ୰ୣ. The metric monitors the SEIRA 
enhancement performance and is solely related to the intrinsic 
signal enhancement properties of the sensing device. The last 
 
Giovanni Pellegrini1, Leonetta Baldassarre2,3, Valeria Giliberti2,3, Jacopo Frigerio4, Kevin Gallacher5, 
Douglas J. Paul5, Giovanni Isella4, Michele Ortolani2, and Paolo Biagioni1 
1Dipartimento di Fisica, Politecnico di Milano, I-20133 Milan, Italy 
2 Dipartimento di Fisica, Sapienza Università di Roma, I-00185 Rome, Italy  
3Center for Life Nano Sciences, Istituto Italiano di Tecnologia, I-00185 Rome, Italy 
4L-NESS, Dipartimento di Fisica del Politecnico di Milano, I-22100 Como, Italy 
5School of Engineering, University of Glasgow, Glasgow, G12 8LT, U.K. 
Benchmarking the use of heavily-doped Ge against noble metals 
for plasmonics and sensing in the mid-infrared  
T 
Fig. 1. Schematic representation of nanoantenna and nanoslit SEIRA sensing 
platform and corresponding baseline corrected reflectance SEIRA signal
(ǻRSEIRA), along with the reference reflectance signal for the same volume 
VSEIRA of target molecules deposited on the bare substrate (ǻRbare). 
	
	  
devised metric aims at the description of the measured SEIRA 
signal under realistic experimental conditions. In a typical 
experiment, a volume ୲ܸ୭୲ ൌ ୗܸ୉୍ୖ୅ ൅ ୠܸୟ୰ୣ of analyte is 
usually delivered to the sensing platform and a reference 
substrate, where for the sensing device only a limited volume 
( ୗܸ୉୍ୖ୅) of the target molecules interacts with the plasmonic 
nanostructure, while the remaining volume fraction ( ୠܸୟ୰ୣ) 
experiences no significant signal enhancement. In order to track 
the signal enhancement between the sensing platform and the 
reference substrate, starting from the quantities ߂ܴୗ୉୍ୖ୅ and 
߂ܴୠୟ୰ୣ, it is then necessary to consider a normalization 
coefficient including  the relative volume fraction of sensitized 
molecules, finally obtaining: 
  
ୣ୶୮ ൌ ൬
߂ܴୗ୉୍ୖ୅
߂ܴୠୟ୰ୣ ൰ ൈ ൬
ୗܸ୉୍ୖ୅
ୠܸୟ୰ୣ
൰Ǥ 
As a practical example, we model and compare the performance 
of Au-based, state-of-the-art SEIRA platforms [3] against the 
newly-designed Ge-based sensing devices. We demonstrate 
that the adopted Ge nano-slit design allows for SEIRA signal 
enhancements, tracked by means of the ୗ୉୍ୖ୅ metric, above 
3 orders of magnitude in the 400-1000 cm-1 energy range [Fig. 
2(a)], with uniform field enhancement inside the nano-slits. The 
signal enhancement compares favorably with the 3 to 4 orders 
of magnitude gain typically obtained with best performing Au-
based platforms characterized by comparable geometrical 
parameters [Fig. 2(b)]. This indicates that plasmonic Ge sensors 
represent a viable alternative to noble metals for integrated 
plasmon enhanced vibrational spectroscopy in the mid-infrared 
range. 
 
The research leading to these results has received funding 
from the European Union’s Seventh Framework Programme 
under grant agreement no. 613055. 
 
REFERENCES 
[1] L. Baldassarre, E. Sakat, J. Frigerio, A. Samarelli, K. Gallacher, E. 
Calandrini, G. Isella, D. J. Paul, M. Ortolani, and P. Biagioni, “Midinfrared 
Plasmon-Enhanced Spectroscopy with Germanium Antennas on Silicon 
Substrates”, Nano Lett., vol. 15, pp. 7225–7231, Nov. 2015. 
[2] B. Dastmalchi, P. Tassin, T. Koschny, and C. M. Soukoulis, “A New 
Perspective on Plasmonics: Confinement and Propagation Length of Surface 
Plasmons for Different Materials and Geometries”, Advanced Optical 
Materials, vol. 4 pp. 177–184, Jan. 2016. 
[3] C. Huch, J. Vogt, M. Sendner, D. Hengstler, F. Neubrech, and A. Pucci, 
“Plasmonic Enhancement of Infrared Vibrational Signals: Nanoslits Versus 
Nanorods”, ACS Photonics, vol. 2 pp. 1489-1497, 2015 
Fig. 2. (a) Local field enhancement and typical SEIRA signal for a Ge sensing
platform operating at 845 cm-1. (b) Local field enhancement and typical SEIRA
signal for a Au sensing platform operating at 3100 cm-1. 


Benchmarking the Use of Heavily-Doped Ge Against Noble Metals for Plasmonics and Sensing in the Mid-Infrared

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