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Akira
Fujiwara
NTT
Basic Research Laboratories
3-1
Morinosato Wakamiya, Atsugi-shi,
Kanagawa,
243-0198 JAPAN
Email:
akira.fujiwara + @ntt.com
Akira Fujiwara was born in Japan, 1967. He received the B.S., M.S.,
and Ph.D. degrees in applied physics from The University of Tokyo, Japan, in
1989,1991, and 1994, respectively. His Ph.D. thesis was entitled "Resonant
electron capture in semiconductor quantum wells". In 1994, he joined LSI
Laboratories, Nippon Telegraph and Telephone (NTT) Corporation, Kanagawa,
Japan. He moved to the Basic Research Laboratories (BRL) in 1996. He was a
guest researcher at National Institute of Standards and Technology (NIST),
Gaithersburg, USA during 2003-2004. For 2006-2020, He was a group leader of Nanodevcies Research
Group, NTT BRL. For 2007-2015, He was a Distinguished Technical Member, NTT
BRL. For 2012-2020, he served as an Senior Manager of Physical Science
Laboratory. Since 2015, He is a NTT Senior
Distinguished Scientist. In 2011-2014 he was supported by the funding
program for Next
Generation World-Leading Researchers (NEXT Program), JSPS. He is now a
leader of the 2018-2022 JSPS
KAKENHI S (Quantum Standards and Ultimate Precision Measurements Based on
Single Electrons) .He is a IEEE fellow and a JSAP (the Japan Society of Applied
Physics) Fellow.
Research Interests
Physics and application of low-dimensional structures
Silicon nanostructures
and their application to nanodevices
Single-electron
devices and their applications
Education
1991 M.S. in Applied
Physics, The University of Tokyo
1994 Ph.D. in Applied
Physics, The University of Tokyo
1989 B.S. in Applied
Physics, The University of Tokyo
Employment
2015- Senior Distinguished Scientist, NTT BRL
2012- Senior Manager of Physical Science Laboratory, NTT BRL
2007-2015 Distinguished technical member, NTT BRL
2006- Group leader of Nanodevices Research Group,
NTT BRL
1996 NTT Basic Research Laboratories (BRL)
1994 NTT LSI Laboratories
Professional Activities
2017.10-2023.9 Science Council of Japan, member
2016 & 2012 &
2019 Examiner of Ph. D. thesis, UNSW
2014 & 2011 &
2008 Examiner of Ph. D. thesis, Tokyo
Tech.
2013.4-2014.3 Visiting Professor, Hokkaido University
2012 Examiner of Ph.
D. thesis, UNSW
2011.4-2012.3 Japanese Society of Applied Physics(JSAP) Executive
Director
2010.4-2011.3 Japanese Society of Applied Physics(JSAP) Director
2003.7-2004.7 Guest
researcher at the National Institute of Standards and Technology (NIST),
Gaithersburg, MD, USA
2007.8 Lecturer(Non-Full-time), The University of
Tokyo
Awards and Honors
JSAP fellow, 2020.9.8
JSAP Silicon Technology Division Paper Award, 2020
IEEE fellow, 2018.1.1
Prizes for Science and Technology, the Minister of Education, Culture, Sports, Science and Technology (MEXT), 2017
Japanese Journal of
Applied Physics (JJAP) Paper Awards, 2013
The Young Scientists’
Prize, the Minister of MEXT (Ministry of Education, Culture, Sports, Science, and
Technology), 2006
Japanese Journal of Applied
Physics (JJAP) Paper Awards, 2006
Japanese Journal of Applied
Physics (JJAP) Paper Awards, 2003
SSDM (International
Conference on Solid State Devices and Materials) Paper Award, 1999
SSDM (International Conference
on Solid State Devices and Materials) Young Researcher Award, 1998
Committee/International Conference Activities
Co-chair of
International Symposium on Nanoscale Transport and Technology ISNTT 2015,
Atsugi, Nov. 2015.
Co-chair of Silicon
Quantum Electronics Workshop, Takamatsu, Aug. 3-4, 2015.
Program vice chair of
Int. Conf. on Solid State Devices and Materials (SSDM2014), Tsukuba, Sept.
2014.
Co-chair of
International Symposium on Nanoscale Transport and Technology ISNTT 2013,
Atsugi, Nov. 2013.
Program vice chair of
Int. Conf. on Solid State Devices and Materials (SSDM2013), Fukuoka, Sept.
2013.
Program vice chair of
APPC12(the 12th Asia Pacific Physics Conference), Makuhari, Japan, July, 2013.2007.8
Co-chair of Workshop
on Innovative Devices and Systems (WINDS) , Hawaii, USA, Dec. 2-7 2012.
Special committee of Emerging Research Devices
WG, STRJ (Semiconductor Technology Roadmap Committee of Japan) 2008.10-
Government Fund
2023-2025 NEDO Project (Quantum traceable ultrasmall current sensing)
2018-2022 JSPS
KAKENHI S (Quantum Standards and Ultimate Precision Measurements Based on
Single Electrons)
2011-2014 The Funding Program
for Next Generation World-Leading Researchers (NEXT Program), JSPS
CV (as of 2024.5.10)
Curriculum Vitae (CV) incl.
publication lists etc.
Publication data (as of
2018.6.15)
http://www.researcherid.com/rid/A-6648-2012
Total: 171 papers, Average Citations 19 h-index 32 (->36 on Jan 16, 2023)
First author: 17 paper, Average Citations 32.94 h-index 11
Google
Scholor Citations (automatically updated)
Recent selected
papers/international conferences (updated on May 10, 2024)
Single-electron transfer and dynamics, Tunable-barrier single-electron transistor and
double quantum dots, Single-dopant
device
[2]
S. Nakamura, D. Matsumaru, G.
Yamahata, T. Oe, D.-H. Chae, Y. Okazaki, S. Takada, M. Maruyama, A. Fujiwara,
and N.-H. Kaneko, Universality and multiplication of GHz-operated silicon pumps
with ppm-level uncertainty, Nano Letters 24, 9 (2024).
[3]
A. Fujiwara, G. Yamahata, N.
Johnson, S. Nakamura, N.-H. Kaneko, Silicon Quantum Dot Single-Electron Pumps
for the Closure of the Quantum Metrology Triangle, ECS Transactions 112, 119
(2023).
[4]
G. Yamahata, N. Johnson, and A.
Fujiwara, Coulomb collisions of hot and cold single electrons in series-coupled
silicon single-electron pumps, Phys. Rev. Appl. 20, 044043 (2023).
[5]
S. Nakamura, D. Matsumaru, G. Yamahata, T. Oe, Y. Okazaki, S.
Takada, M. Maruyama, A. Fujiwara, and N.-H.
Kaneko, Cryogenic operation of electromechanical relay for reversal of
quantized current generated by a single-electron pump, IEEE Trans. Inst. Meas.
72, 1502809, (2023).
[6]
S. P. Giblin, G. Yamahata, A. Fujiwara and M. Kataoka, Precision
measurement of an electron pump at 2 GHz; the frontier of small DC current
metrology, Metrologia 60, 055001 (2023).
[7]
A. Fujiwara, G. Yamahata, N. Johnson, Device simulator for optimal
design of silicon single-electron pumps, 2022 Conference on Precision
Electromagnetic Measurements (CPEM 2022) (Wellington, December 12-16 2022).
[8]
G. Yamahata, Johnson, and A. Fujiwara, Understanding the mechanism
of tunable-barrier single-electron pumping, Mechanism crossover and optimal
accuracy, Phys. Rev. B 103, 245306 (2021).
[9]
S. P. Giblin, E. Mykkänen, A. Kemppinen, P. Immonen, A. J. Manninen,
M. Jenei, M. Möttönen, G. Yamahata, A. Fujiwara
and M. Kataoka, Realisation of a
quantum current standard at liquid helium temperature with sub-ppm
reproducibility, Metrologia 57, 025013
(2020).
[10]
(Published in Nature
Nanotech. !)G. Yamahata, S. Ryu, N. Johnson, H-S. Sim, A. Fujiwara, and M.
Kataoka, Picosecond coherent electron motion in a silicon single-electron
source, Nature Nanotechnology 14, 1019–1023 (2019).
[11]
N. Johnson, G. Yamahata, and A. Fujiwara, Measurement of the
curvature and height of the potential barrier for a dynamic quantum dot, Appl.
Phys. Lett. 115, 162103 (2019).
[12]
S. Giblin, A. Fujiwara, G. Yamahata, M. H. Bae, N. Kim, A. Rossi, M.
Möttönen, and M. Kataoka, Evidence for universality of tunable-barrier electron
pumps, Metrologia 56, 044004 (2019).
[13]
G. Yamahata, S. P. Giblin, M. Kataoka, and T. Karasawa, and A. Fujiwara,
High-accuracy current generation in the nanoampere regime from a silicon
single-trap electron pump, Scientific Reports 7, 45137 (2017).
[14]
G. Yamahata, S. P. Giblin, M. Kataoka, T. Karasawa, and A. Fujiwara,
Gigahertz single-electron pumping in silicon with an accuracy better than 9.2
parts in 107, Appl. Phys. Lett. 109, 013101 (2016).
( See
http://www.npl.co.uk/news/record-speed-and-accuracy-achieved-with-single-electron-pumps
)
[15]
G. Yamahata, T. Karasawa, and A. Fujiwara, Gigahertz single-hole
transfer in Si tunable-barrier pumps, Appl. Phys. Lett. 106, 023112 (2015).
[16]
G. Yamahata, K. Nishiguchi, and A. Fujiwara, Gigahertz single-trap
electron pumps in silicon, Nat. Commun. 5, 5038 (2014).
[17]
G.
Yamahata, K. Nishiguchi, and A. Fujiwara: Accuracy evaluation and mechanism
crossover of single-electron transfer in Si tunable-barrier turnstiles Phys.
Rev. B 89, 165302 (2014).
[18]
G. Lansbergen, Y. Ono and A. Fujiwara: Donor based single electron pumps with tunable donor
binding energy, Nano Lett. 12 763−768 (2012).
[19] G. Yamahata, K.
Nishiguchi, and A. Fujiwara: Accuracy evaluation of single-electron huttle
transfer in Si nanowire metal-oxide-semiconductor field-effect transistors,
Appl. Phys. Lett. 98, 222104 (2011).
[20] S. Miyamoto, K.
Nishiguchi, Y. Ono, K. M. Itoh, and A. Fujiwara: Resonant escape over an
oscillating barrier in a single-electron ratchet transfer, Phys. Rev. B 82,
033303 (2010).
[21] S. Miyamoto, K.
Nishiguchi, Y. Ono, K M. Itoh, and A. Fujiwara: Escape dynamics of a few
electrons in a single-electron ratchet using silicon nanowire
metal-oxide-semiconductor field-effect transistor, Appl. Phys. Lett. 93,
222103 (2008).
[22] A. Fujiwara, K.
Nishiguchi, and Y. Ono: Nanoampere charge pump by single-electron
ratchet using silicon nanowire metal-oxide-semiconductor field-effect
transistor: Appl. Phys. Lett. 92, 042102 (2008).
[23] H. W. Liu, T.
Fujisawa, Y. Ono, H. Inokawa, A. Fujiwara, K. Takashina, and Y. Hirayama:
Pauli-spin-blockade transport through a silicon double quantum dot, Phy. Rev. B 77, 073310 (2008).
[24]
M. A. H. Khalafalla, Y. Ono, K. Nishiguchi, and A.
Fujiwara: Identification of single and coupled acceptors in silicon
nano-field-effect transistors, Applied
Physics Letters 91, 263513 (2007).
[25] A. Fujiwara, H. Inokawa, K. Yamazaki, H.
Namatsu, Y. Takahashi, N. M. Zimmerman, and S. B. Martin: Single electron
tunneling transistor with tunable barriers using silicon nanowire
metal-oxide-semiconductor field-effect transistor, Appl. Phys. Lett. 88 053121 (2006).
[26]
A. Fujiwara,
N. M. Zimmerman, Y. Ono, and Y. Takahashi: Current quantization due to
single-electron transfer in Si-wire charge-coupled devices, Appl. Phys. Lett. 84, 1323-1325 (2004).
[27]
A.
Fujiwara and Y. Takahashi: Manipulation of elementary charge in a silicon
charge-coupled device, Nature 410, 560-562 (2001).
Single-electron detection and counting
statistics / stochastic resonance
[2]
K. Chida, A. Fujiwara, and K. Nishiguchi, Seebeck effect in a
nanometer-scale dot in a Si nanowire observed with electron counting statistics,
Appl. Phys. Lett. 121, 183501 (2022). (Cover page !)
[3]
K Nishiguchi, K Chida, and A Fujiwara, Single-electron manipulation
in a attofarad-capacitor, ECS Transactions 104, 33 (2021).
[4]
(Published in Nature Com. !) K Chida, S. Desai, K Nishiguchi, and A
Fujiwara: Power generator driven by Maxwell's demon, Nat. Commun.
8, 15310 (2017).
[5]
K Chida, K Nishiguchi, G Yamahata, H Tanaka, A Fujiwara:
Thermal-noise suppression in nano-scale Si field-effect transistors by feedback
control based on single-electron detection, Appl. Phys. Lett. 107, 073110, 2015 (2015).
[6]
P. A. Carles, K Nishiguchi, and A Fujiwara: Deviation from the law
of energy equipartition in a small dynamic-random-access memory, Jpn. J. Appl.
Phys. 54, 06FG03 (2015).
[7]
K. Nishiguchi, Y. Ono, and A. Fujiwara: Single-electron thermal
noise, Nanotechnology 25, 275201 (2014).
[8] K. Nishiguchi, H.
Yamaguchi, A. Fujiwara, H. S. J. van der Zant, and G. A. Steele, Wide-bandwidth
charge sensitivity with a radio-frequency field-effect Transistor, Appl. Phys.
Lett. 103, 143102 (2013).
[9] K. Nishiguchi and
A. Fujiwara: Detecting signals buried in noise via nanowire transistors
using stochastic resonance, Appl. Phys. Lett. 101, 193108 (2012).
[10] K. Nishiguchi and
A. Fujiwara: Single-Electron Stochastic Resonance Using Si Nanowire
Transistors, Jpn. J. Appl. Phys. 50, 06GF04 (2011)..
[11]
K. Nishiguchi, N. Clement, T. Yamaguchi, and A.
Fujiwara: Si nanowire ion-sensitive field-effect transistors with a shared
floating gate, APPLIED PHYSICS LETTERS 94,
163106 (2009).
[12]
K. Nishiguchi and A. Fujiwara: Single-electron
counting statistics and its circuit application in nanoscale field-effect
transistors at room temperature, Nanotechnology
20 175201 (2009).
Functional nanotransistors, sensors,
molecular electronics
[2]
S. Li, Y. Coffinier, C. Lagadec, F. Cleri, K. Nishiguchi, A. Fujiwara,
S. H. Kim, and N. Clement, Single-Cell Electrochemical Aptasensor Array, ACS
Sens. 8, 2921 (2023).
[3]
K. Nishiguchi, H. Yamaguchi, A. Fujiwara, H. S. J. Van Der Zant, and
G. A. Steele, Room-temperature several-hundred-of-megahertz charge sensing with
single-electron resolution using a silicon transistor, Appl. Phys. Lett. 122,
043502 (2023).
[4]
K. Nishiguchi, H. Yamaguchi, and A. Fujiwara, Subgigahertz
Multilayer-Graphene Nanoelectromechanical System Integrated with a
Nanometer-Scale Silicon Transistor Driven by Reflectometry, Phys. Rev. Appl.
19, L011003 (2023).
[5]
S. Li, Y. Coffinier, C. Lagadec, F. Cleri, K. Nishiguchi, A.
Fujiwara, T. Fujii, S–H. Kim, N.
Clement, Redox-labelled electrochemical aptasensors with nanosupported
cancer cells, Biosensors and Bioelectronics 216, 114643 (2022).
[6]
M Razanoelina, M Hori, A Fujiwara, and Y Ono, Critical conductance
of two-dimensional electron gas in silicon-on-insulator
metal-oxide-semiconductor field-effect transistor, Appl. Phys. Express 14,
104003 (2021).
[7]
(Published in Nature Com
!) H. Firdaus, T. Watanabe, M. Hori, D.
Moraru, Y. Takahashi, A. Fujiwara, and Y. Ono, Electron aspirator using
electron–electron scattering in nanoscale silicon, Nature Communications 9,
4813 (2018)
[8]
(Published in Nature Materials !) R. Sivakumarasamy, R. Hartkamp, B. Siboulet,
J.-F. Dufreche, K. Nishiguchi, A. Fujiwara, and N. Clément,
Selective-layer-free Blood Serum Ionogram based on Ion-specific Interactions with
a Nanotransistor, Nature Materials 17 464 (2018).
[9]
N. Clement and A. Fujiwara, Molecular diodes: Breaking the Landauer
limit, Nat. Nanotech. 12, 725 (2017).
[10] N. Clément,
K. Nishiguchi, J. F. Dufreche, D. Guerin, A. Fujiwara, and D. Vuillaume,
Water Electrolysis and Energy Harvesting with Zero-Dimensional Ion-Sensitive
Field-Effect Transistors, Nano Lett. 13, 3903−3908 (2013).
[11] I. Mahboob, K.
Nishiguchi, A. Fujiwara, and H. Yamaguchi, Phonon Lasing in an
Electromechanical Resonator , Phys. Rev. Lett. 110 127202 (2013).]
[12] N. Clément, K.
Nishiguchi, J. F. Dufreche, D. Guerin, A. Fujiwara, and D. Vuillaume, A
silicon nanowire ion-sensitive field-effect transistor with elementary charge
sensitivity, Appl. Phys. Lett. 98, 014104 (2011).
[13] I. Mahboob, E.
Flurin, K. Nishiguchi, A. Fujiwara, and H. Yamaguchi: Nature
Communications 2, 198 doi:10.1038/ncomms1201 (2011).
[14]
N. Clément, K. Nishiguchi, A. Fujiwara and D.
Vuillaume: One-by-one trap activation in silicon nanowire transistors, Nature
Communications 1 DOI:10.1038/ncomms1092 (2010).
Silicon quantum well and optical properties
[2]
J. Noborisaka, K. Nishiguchi, A. Fujiwara: Electric tuning of
direct-indirect optical transitions in silicon, Scientific Reports 4, 6950
(2014).
[3]
J. Noborisaka, K. Nishiguchi, Y. Ono, H. Kageshima,
and A Fujiwara: Strong Stark effect in electroluminescence from
phosphorous-doped silicon-on-insulator metal-oxide-semiconductor field-effect
transistors, Appl. Phys. Lett. 98, 033503 (2011).
[4]
J. Noborisaka, K. Nishiguchi, H. Kageshima, Y. Ono,
and A Fujiwara: Tunneling spectroscopy of electron subbands in thin
silicon-on-insulator metal-oxide-semiconductor field-effect transistors, Appl.
Phys. Lett. 96, 112102 (2010).
Physics of
Si 2DEG and valley physics in collaboration
with Prof. Hirayama (Tohoku Univ. ) and Dr. Takashina (Univ. of Bath) , Dr.
Vincent Renard (CEA)
[1]
V. T. Renard, B. A. Piot, X. Waintal, G. Fleury, D. Cooper, Y.
Niida, D. Tregurtha, A. Fujiwara, Y. Hirayama and K. Takashina, Valley
polarization assisted spin polarization in two dimensions, Nat. Commun. 6, 7230
(2015).
[2] V. T. Renard, I.
Duchemin, Y. Niida, A. Fujiwara, Y. Hirayama and K. Takashina, Metallic
behaviour in SOI quantum wells with strong intervalley scattering, Scientific
reports | 3 : 2011 | DOI: 10.1038/srep02011 (2013).
[3] K. Takashina, Y.
Niida, V. T. Renard, B. A. Piot, D. S. D. Tregurtha, A. Fujiwara, and Y.
Hirayama, Phys. Rev. B 88, 201301(R) (2013).
[4] Y. Niida, K. Takashina,
Y. Ono, A. Fujiwara and Y. Hiryama: Electron and hole mobilities at a Si/SiO2 interface with
giant valley splitting, Appl. Phys. Lett. 102, 191603 (2013).
[5] K. Takashina, Y. Niida, V. T.
Renard, A. Fujiwara, T. Fujisawa, K. Muraki, and Y.Hirayama: Impact of Valley
Polarization on the Resistivity in Two Dimensions, Phys. Rev. Lett. 106,
196403 (2011).
[6] K. Takashina, K. Nishiguchi,
Y. Ono, A. Fujiwara, T. Fujisawa, Y. Hirayama, and K. Muraki: Electrons and
holes in a 40 nm thick silicon slab at cryogenic temperatures, APPLIED PHYSICS LETTERS 94, 142104
(2009).
[7] Y. Niida, K. Takashina, A.
Fujiwara, T. Fujis awa, and Y. Hirayama:
Spin splitting of upper electron subbands in a SiO2/Si(100)/SiO2 quantum well
with in-plane magnetic field, APPLIED
PHYSICS LETTERS 94, 142101 (2009).
Invited talk:
[2]
A.
Fujiwara, G. Yamahata, N. Johnson, S. Nakamura, and N. -H. Kaneko, Silicon
quantum dot single-electron pumps for the closure of the quantum metrology
triangle, 244th The Electrochemical Society (ECS) Meeting (Oct. 8-12, 2023,
Gothenburg, Sweden).
[3]
A.
Fujiwara, and G. Yamahata, Metrology application of silicon single-electron
pumps, 2023 Asia-Pacific Workshop on Advanced Semiconductor Devices (AWAD 2023)
(Jul. 10-11, 2023, Yokohama, Japan).
[4]
A.
Fujiwara, G. Yamahata, N. Johnson, Electron manipulation using a silicon
dynamic quantum dot, Workshop for the single-electron quantum technology, (Nov.
25-26, 2022, Buyeo, Korea).
[5]
A.Fujiwara,
G. Yamahata, N. Johnson, Electron dynamics and device simulation of silicon
single-electron pumps, Single-Electron Quantum Optics for Metrology Workshop
(SEQUOIA Meeting) (October 11-12, 2021, Online, France).
[6]
A.
Fujiwara, G. Yamahata, N. Johnson, S. Ryu, H-S. Sim, and M. Kataoka, Fast
electron dynamics in a silicon dynamic quantum dot, The International Workshop
on Computational Nanotechnology (IWCN)
(May 24 –June 6, 2021, Online, Korea).
[7]
A.
Fujiwara, G. Yamahata, N. Johnson, S. Ryu, H-S. Sim, and M. Kataoka, Fast
electron dynamics in a silicon dynamic quantum dot, Int. Workshop on Cool
Electrons in Flatlands (CEF2020) (June 15-24, 2020, Catania, Italy, held as
virtual workshop)
[8]
A.
Fujiwara, Silicon nanodevices for metrology and sensor applications, IEEE
Nanotechnology Materials and Devices Conference (IEEE NMDC2019) (Oct.. 27-30,
2019, Stockholm, Sweden)
[9]
A.
Fujiwara, Ultimate electronics with silicon nanowire MOSFETs, Workshop on
Innovative Nanoscale Devices and Systems (WINDS) (Nov. 25-30, 2018, Hawaii,
USA)
[10]
A.
Fujiwara, G. Yamahata, K. Chida, and K. Nishiguchi, Tunable-barrier electron
pump for quantum current standards and information-to-energy converters
China-Japan International Workshop on Quantum Technologies, QTech2018 (Aug
23-24, 2018, Hefei, China).
[11]
A.
Fujiwara, Ultimate electronics with control of single electrons, 7th Summer
School on Semiconductor/Superconducting Quantum Coherence Effect and Quantum
Information (August 27-29, 2017, Shuzenji, Japan).
[12]
A.
Fujiwara, K. Nishiguchi, G. Yamahata, and K. Chida, Ultimate electronics with
control of single electrons, EM-NANO2017 (June 18-21, 2017, Fukui, Japan).
[13]
A.
Fujiwara, K. Nishiguchi, G. Yamahata, and K. Chida, Ultimate Single Electronics
with Silicon Nanowire MOSFETs, 2017 Silicon Nanoelectronics Workshop (June 4-5,
2017, Kyoto, Japan).
[14]
A.
Fujiwara, G. Yamahata, K. Nishiguchi, S. P. Giblin, and M. Kataoka, Gigahertz
single-electron pump for quantum current standard, 33rd ICPS (Beijing, 31 July- 5 August, 2016)
[15]
A. Fujiwara, G. Yamahata, and K.
Nishiguchi, Gigahertz Single-Electron Pump towards a Representation of the New
Ampere, 2015 SSDM (Sapporo, 27-30 September, 2015).
[16]
A. Fujiwara, G. Yamahata, J. Noborisaka,
and K. Nishiguchi, Nanoscale Silicon MOSFET for Metrology and Valleytronics
Applications, 2015 UK-Japan Silicon Nanoelectronics and Nanotechnology
Symposium (Southampton, 9-10 July, 2015).
[17]
(Plenary talk) A. Fujiwara,
Silicon single-electron devices for ultimate electronics, EURAMET DC &
Quantum Metrology Meeting (Bern, 27-29 May 2015)
[18]
A.
Fujiwara, K. Nishiguchi, G. Yamahata, Silicon nanowire MOSFETs for diverse
applications, The 6th IEEE International Nanoelectronics Conference 2014
(INEC2014) (Sapporo, July 28-31, 2014)
[19] (Plenary talk) A. Fujiwara, Silicon-based
nanodevices for diverse applications, 39th Int. Conf. on Micro and
Nano Engineering (MNE) (London, UK, Sept. 16-19 2013).
[20] A. Fujiwara, G. Yamahata, K. Nishiguchi, G.
P. Lansbergen and Y. Ono: Silicon Single-Electron Transfer Devices: Ultimate
Control of Electric Charge, 2012 Silicon Nanoelectronics Workshop (June 2012,
Hawaii, USA).
[21] A. Fujiwara, K. Nishiguchi, and Y. Ono:
Single electron transfer technology using Si nanowire MOSFETs, 2010 International Symposium on Atom-scale Silicon
Hybrid Nanotechnologies for ‘More-than-MooreE& ‘Beyond CMOSEEra (March
1 E 2, 2010, Southampton, UK), Program and Abstracts, pp. 19 E20.)
[22] A. Fujiwara, K. Nishiguchi and Y. Ono:
Single-electron devices based on silicon nanowire MOSFETs, Trends in
Nanotechnology (TNT2009) p.39 (September 7-11, 2009,Barcelona)
[23] A. Fujiwara, K. Nishiguchi and Y. Ono:
Silicon Nanowire MOSFETs and Their Application to Single-Electron Devices,
International Conference on Nanoscience and Technology (ChinaNANO) 2009, p.
50-51 (September 1-3, 2009,Beijing)
[24] A. Fujiwara, K. Nishiguchi, Y. Ono, H.
Inokawa, and Y. Takahashi: Silicon Single-Electron Devices and Their
Applications, 2008 Tera-level NanoDevices
(TND) Technical Forum (Soul, 2008.10.17).
[25] A. Fujiwara and Y. Takahashi: Si
nano-devices using an electron-hole system, 2nd
International Conference on Semiconductor Quantum Dots (QD2002) (2002.9).
[26] A. Fujiwara and Y. Takahashi: Si
nano-devices using an electron-hole system, Proceedings
of 5th Europian Workshop on Low Temperature Electronics, (Journal de Physiqye
IV, 12, No.Pr3), Ed. F Balestra,
(WOLTE-5) pp. Pr3-85-Pr3-92 (2002.6).
[27] A. Fujiwara, K. Yamazaki, and Y. Takahashi:
Silicon Single-electron CCD, 2001 Int.
Micreprocess and Nanotechnology Conference (MNC) pp. 278-279 (2001.10).
[28] A. Fujiwara, Y. Takahashi, K. Yamazaki, H.
Namatsu, M. Nagase, K. Kurihara, and K. Murase
Single-electron devices: recent attempts towards high performance and
functionality, 1999 Int. Conf. Solid
State Devices and Materials (SSDM) pp. 248-249 (1999).
[29] A. Fujiwara, Y. Takahashi, K. Yamazaki, H.
Namatsu, M. Nagase, K. Kurihara, and K. Murase: Silicon single-electron devices
fabricated by pattern-dependent oxidation (PADOX), Sweden-Japan Joint QNANO Workshop (1998).
[30] A. Fujiwara, Y. Takahashi, K. Yamazaki, H.
Namatsu, M. Nagase, K. Kurihara, and K. Murase: Silicon single-electron devices
fabricated by pattern-dependent oxidation (PADOX), International Symposium on Formation, Physics and Device Application of
Quantum Dot Structures (QDS98), (1998).
Selected first-author papers
[2] A. Fujiwara, K. Nishiguchi, and Y. Ono:
Nanoampere charge pump by
single-electron ratchet using silicon nanowire metal-oxide-semiconductor
field-effect transistor: Applied Physics Letters 92, 042102 (2008).
[3]
A. Fujiwara, H. Inokawa, K. Yamazaki, H.
Namatsu, Y. Takahashi, N. M. Zimmerman, and S. B. Martin: Single electron
tunneling transistor with tunable barriers using silicon nanowire
metal-oxide-semiconductor field-effect transistor, Applied Physics Letters
88 053121 (2006).
[4]
A. Fujiwara, N. M. Zimmerman, Y. Ono, and
Y. Takahashi: Current quantization due to single-electron transfer in Si-wire
charge-coupled devices, Applied Physics Letters 84, 1323-1325 (2004).
[5] A. Fujiwara, S. Horiguchi, M. Nagase, and
Y. Takahashi: Threshold voltage of Si single-electron transistor, Japanese
Journal of Applied Physics Part 1-Regular Papers Short Notes & Review
Papers 42, 2429-2433 (2003).
[6] A. Fujiwara, K. Yamazaki, and Y. Takahashi:
Detection of single charges and their generation-recombination dynamics in Si
nanowires at room temperature, Applied Physics Letters 80,
4567-4569 (2002).
[7] A. Fujiwara and Y. Takahashi: Mechanism of
single-charge detection using electron-hole system in Si-wire transistors, Japanese
Journal of Applied Physics Part 1-Regular Papers Short Notes & Review
Papers 41, 1209-1213 (2002).
[8] A.
Fujiwara and Y. Takahashi: Manipulation of elementary charge in a silicon
charge-coupled device, Nature 410, 560-562 (2001).
[9] A. Fujiwara, Y. Takahashi, K. Yamazaki, H.
Namatsu, M. Nagase, K. Kurihara, and K. Murase: Double-island single-electron
devices - A useful unit device for single-electron logic LSI's, IEEE Transactions
on Electron Devices 46, 954-959 (1999).
[10] A. Fujiwara, Y. Takahashi, H. Namatsu, K.
Kurihara, and K. Murase: Suppression of effects of parasitic
metal-oxide-semiconductor field-effect transistors on Si single-electron
transistors, Japanese Journal of Applied Physics Part 1-Regular Papers Short
Notes & Review Papers 37, 3257-3263 (1998).
[11]
A. Fujiwara, Y. Takahashi, and K. Murase:
Observation of single electron-hole recombination and photon-pumped current in
an asymmetric Si single-electron transistor, Physical Review Letters 78, 1532-1535 (1997).
[12] A. Fujiwara, Y. Takahashi, K. Murase, and
M. Tabe: Time-Resolved Measurement of Single-Electron Tunneling in a Si
Single-Electron Transistor with Satellite Si Islands, Applied Physics
Letters 67, 2957-2959 (1995).