Nanotechnology and Energy: Armchair Quantum Wires The Power Conference ‘06 UH - GEMI June 29 , 2006 Wade Adams, Howard Schmidt, Bob Hauge, Amy Jaffe, and Rick.
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Transcript Nanotechnology and Energy: Armchair Quantum Wires The Power Conference ‘06 UH - GEMI June 29 , 2006 Wade Adams, Howard Schmidt, Bob Hauge, Amy Jaffe, and Rick.
Nanotechnology and Energy:
Armchair Quantum Wires
The Power
Conference ‘06
UH - GEMI
June 29 , 2006
Wade Adams, Howard Schmidt, Bob Hauge,
Amy Jaffe, and Rick Smalley*
www.nano.rice.edu
www.rice.edu/energy
*deceased
Professor Richard E. Smalley
1943 - 2005
Nobel Prize in Chemistry 1996
A 6 week
summer
project in
1985
2 – page
paper in
Nature
with Robert
F. Curl and
Harold
Kroto
C60
Buckminsterfullerene:
Buckyballs
National Nanotechnology Program
White House – November 2003
Humanity’s Top Ten Problems
for next 50 years
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
ENERGY
WATER
FOOD
ENVIRONMENT
POVERTY
TERRORISM & WAR
DISEASE
EDUCATION
DEMOCRACY
POPULATION
2003
2050
6.5
8-10
Billion People
Billion People
The ENERGY REVOLUTION
(The Terawatt Challenge)
50
45
40
35
30
25
20
15
10
5
0
50
2003
2050
45
14 Terawatts
40
210 M BOE/day
35
30 -- 60 Terawatts
450 – 900 MBOE/day
30
25
0.5%
20
10
5
r,
w
in
d
al
,g
eo
ro
el
th
ec
t
er
m
ric
s
Hy
d
Bi
o
n
io
n
/F
i ss
io
Ga
s
m
as
So
la
20st Century = OIL
21st Century = ??
Fu
s
The Basis of Prosperity
Co
a
Energy:
l
0
Oi
l
Source: Internatinal Energy Agency
Bi
om
as
H
s
So
yd
ro
la
r,
el
ec
w
in
tri
d,
c
ge
ot
he
rm
al
io
n
Fi
ss
as
G
al
Co
O
il
15
Energy-efficient Commuting
PRIMARY ENERGY SOURCES
Alternatives to Oil
TOO LITTLE
• Conservation / Efficiency
• Hydroelectric
• Biomass
• Wind
• Wave & Tide
------
CHEMICAL
• Natural Gas
• Gas Hydrates
• Clean Coal
-- sequestration?, cost?
-- sequestration?, cost?
-- sequestration?, cost?
NUCLEAR
•
Nuclear Fission
•
Nuclear Fusion
•
Geothermal HDR
•
Solar terrestrial
•
Solar power satellites
•
Lunar Solar Power
-------
not enough
not enough
not enough
not enough
not enough
radioactive waste?, terrorism?, cost?
too difficult?, cost?
cost ? , enough?
cost ?
cost ?
cost ?
165,000 TW
of sunlight
hit the earth
every day
PV Land Area Requirements
Nathan S. Lewis, California
Institute of Technology
3 TW
20 TW
Solar Cell Land Area Requirements
Nathan S. Lewis, California
Institute of Technology
6 Boxes at 3.3 TW Each = 20 TWe
≥ 20 TWe from the Moon
“Harvested
Moon”
David Criswell
Univ. Houston
Renewable Resource Maps
Renewable sources generally remote from major population centers
Source: NREL
US Power Production Map
Currently, power is generated close to population centers
Source: DOE & Nate Lewis, Caltech
One World Energy Scheme for 30-60TW in 2050:
The Distributed Store-Gen Grid
• Energy transported as electrical energy over wire, rather than by
transport of mass (coal, oil, gas)
• Vast electrical power grid on continental scale interconnecting ~ 100
million asynchronous “local” storage and generation sites, entire
system continually innovated by free enterprise
• “Local” = house, block, community, business, town, …
• Local storage = batteries, flywheels, hydrogen, etc.
• Local generation = reverse of local storage + local solar and geo
• Local “buy low, sell high” to electrical power grid
• Local optimization of days of storage capacity, quality of local power
• Electrical grid does not need to be very reliable, but it will be
robust
• Mass Primary Power input to grid via HV DC transmission lines from
existing plants plus remote (up to 2000 mile) sources on TW scale,
including vast solar farms in deserts, wind, NIMBY nuclear, clean
coal, stranded gas, wave, hydro, space-based solar…”EVERYBODY
PLAYS”
• Hydrogen, methanol, ethanol are transportation fuels
• Transition technology – Plug-in Hybrids
Energy Nanotech Grand Challenges
from Meeting at Rice University May 2003
Report available!
1.
Photovoltaics -- drop cost by 100 fold.
2.
Photocatalytic reduction of CO2 to methanol.
3.
Direct photoconversion of light + water to produce H2.
4.
Fuel cells -- drop the cost by 10-100x + low temp start.
5.
Batteries and supercapacitors -- improve by 10-100x for automotive
and distributed generation applications.
6.
H2 storage -- light weight materials for pressure tanks and LH2
vessels, and/or a new light weight, easily reversible hydrogen
chemisorption system
7.
Power cables (superconductors, or quantum conductors) with which
to rewire the electrical transmission grid, and enable continental, and
even worldwide electrical energy transport; and also to replace
aluminum and copper wires essentially everywhere -- particularly in
the windings of electric motors and generators (especially good if we
can eliminate eddy current losses).
Carbon
Nanotechnology
Laboratory
Making Buckytubes
“Be All They Can Be”
Founded by Rick Smalley in 2003 as a division of CNST
Coordinates SWNT Research with 10 Faculty in 6 Departments
Prof. James M. Tour – Director
Prof. Matteo Pasquali – Co-Director
Dr. Howard K. Schmidt - Executive Director
Dr. Robert H. Hauge - Technology Director
If it ain’t tubes, we don’t do it!
Why Single Wall Carbon Nanotubes?
MOLECULAR PERFECTION & EXTREME PERFORMANCE
The Strongest Fiber Possible.
Selectable Electrical Properties
Metallic Tubes Better Than Copper
Semiconductors Better Than InSb or GaAs
Thermal Conductivity of Diamond.
The Unique Chemistry of Carbon.
The Scale and Perfection of DNA.
The Ultimately Versatile Engineering Material.
Graphene Sheet
Texas Chicken Wire
SWNT: ROLLED-UP SHEET OF GRAPHITE
World’s largest SWNT model
RAJAT DUGGAL
(inside giant SWNT model)
22 April 2005, Guinness World Record
Model of a 5-5 SWNT
~65,000 pieces
360 m long, 0.36 m wide
about 100 builders
over 1000 in attendance
“Supremely Silly” (from Rick Smalley)
Cost of the parts: $6,000
Building a 1000-ft SWNT:
pRICEless
Types of SWNT
– Cylindrical graphene sheet
– Diameters of 0.7 – 3.0 nm
armchair (a = 30°)
• Observed tubes typically < 2 nm
– Both metallic and semiconductor species possible
– Length to diameter ratio as
large as 104 – 105
zigzag (a = 0°)
• can be considered 1-D
nanostructures
intermediate (0 a 30°)
Conductivity of Metallic SWNT
•
Measurements on individual metallic
SWNT on Si wafers with patterned
metal contacts
•
Single tubes can pass 20 uA for hours
•
Equivalent to roughly a billion amps
per square centimeter!
•
Conductivity measured twice that of
copper
•
Ballistic conduction at low fields with
mean free path of 1.4 microns
•
Similar results reported by many
•
Despite chemical contaminants and
asymmetric environment
Dekker, Smalley, Nature, 386, 474-477 (1997). McEuen, et al, Phys.Rev.Lett.84, 6082
Quantum Tunneling
Alper Buldum and Jian Ping Lu, Phys. Rev. B 63, 161403 R (2001).
Tunneling Evidence
• Indirect indication of conductivity
by measuring lifetimes of photoexcited electrons
• Cooling mechanism is interaction
with phonons – just like electrical
resistivity
• Anomalously long life-times yield
mean free path of 15 microns (10x
single tubes)
• Based on bundles in
‘buckypapers’ – good local
symmetry and clean, but still
based on mixture of metals and
semi-conductors
• Results imply 10 – 25x better
conductivity than copper
Source: Tobias Hertl, et al, Phys. Rev. Lett. 84(21) (2000) 5002
SWNT Quantum Wire
Expected Features
• 1-10x Copper Conductivity
• 6x Less Mass
• Stronger Than Steel
• Zero Thermal Expansion
Key Grid Benefits
• Reduced Power Loss
• Low-to-No Sag
• Reduced Mass
• Higher Power Density
SWNT Technology Benefits
• Type & Class Specific
• Higher Purity
• Lower Cost
• Polymer Dispersible
CNL Armchair Quantum Wire
Program
(armchair swnt wire with electrical conductivity > copper)
( 5 years, $25 million )
•
•
•
•
•
SWNT Sorting (the “signal” for the amplifier)
SWNT Amplifier
SWNT Purification
SWNT Fiber Spinning & Processing
SWNT Continuous Growth
Getting The Right Tube
• Often Need A Single Type of SWNT
• Current Growth Inadequate
– Mixtures ~ 50 Types
– Mixed Metals, Semi-Metals &
Semiconductors
– Impure & Inefficient
• N,M Control Critical
–
–
–
–
Quantum Wire
Electronics & Sensors
Biomedical Therapeutics
Energy Conversion Storage
• Seeded Growth Required
–
–
–
–
Separates Nucleation From Growth
Eliminate By-Products & Purification
Vastly Improved Efficiency
Sort Once at Small Scale
Rolling Graphite - n,m Vectors
Chiral
angle
0,0
1,0
2,0
1,1
3,0
1,1
4,0
3,1
2,2
Zigzag
5,0
4,1
3,2
5,1
4,2
3,3
7,0
6,0
6,1
5,2
7,1
6,2
4,3
5,3
4,4
Ar
mc
8,0
ir
8,1
7,2
6,3
5,4
ha
9,0
9,1
8,2
7,3
6,4
5,5
10,0
10,1
9,2
8,3
7,4
6,5
12,0
11,1
10,2
9,3
8,4
7,5
6,6
11,0
10,3
8,5
7,6
11,3
9,6
8,7
11,5
10,6
9,7
8,8
12,3
11,4
10,5
9,5
13,1
12,2
10,4
8,6
7,7
12,1
11,2
9,4
13,0
10,7
9,8
SWNT Excitation Fluorescence
Excitation wavelength (nm) [vn cn transition]
Each peak comes from a specific semi-conducting SWNT n,m value
900
0.3000
0.2323
0.1798
0.1392
0.1078
0.08348
0.06463
0.05004
0.03875
0.03000
0.02323
0.01798
0.01392
0.01078
0.008348
0.006463
0.005004
0.003875
0.003000
800
700
600
500
400
300
900
1000
1100
1200
1300
1400
Emission wavelength (nm) [c1v1 transition]
1500
SWNT Seeded Growth
Current Results
1. Attach Catalyst
2. Deposit on Inert Surface
Key Starting Materials
• Have FeMoC Catalyst
• Have Short SWNT Seeds
• Have Soluble SWNT
Key Process Steps
• In-Solution Attachment
• Controlled Deposition
• Catalyst Docking
• Reductive Etching
• Growth is Next !!
4. SWNT Growth
3. “Dock” Catalyst
SWNTcat Growth
Initial
100 mtorr CH4 – 10 min – 800 oC
46 nm long
120 nm long
0.6 nm
0.6 nm
1.8 nm
0.6 nm
1.0 nm
SWNT Amplifier
Process Flow
Attach
Disperse
Grow
Dock
Cut
SWNTamp Production Concept
Hydro-carbon
feedstocks
SWNT+ FeMoC Catalyst
Seeded Growth
500 < T < 700 C
Mono-Type SWNT
(1000 lb / day )
Bulk
Output
“Inner Loop” Processing
Seed Preparation. (1 lb/ day)
Cut SWNT, Prep. Catalyst,
Functionalize, Attach, Dock
SWNT Growth Rates
SWNT Sample
SWNTcat on HOPG
SWNT Fiber Continued Growth
Maruyama Carpet Growth
Hata Carpet Growth
Free SWNT Growth
Growth Rate (mm/min)
0.005
0.3
1
250
600
DNA Replication (Bacteria)
0.340
Science 306, 1362 (2004).
Nano Lett. 4, 1025 (2004).
Production Scale-Up Path
• Rice made 1 mg / day in 1997
• Lab-scale reactor at 1 gm / hour (2002)
• CNI Pilot plant producing 20 lb /day
• CNI now testing 100 lb / day reactor
Forming SWNT Wires
• Need macro-crystalline SWNT fiber/wire
• Starting material is tangled at several scales
• Starting material has variety of diameters and
types
• Enormous Van der Waals forces make it hard
to separate SWNT bundles
Dispersion in Super-Acids
• SWNT bundles swell in superacids
• Dispersion due to “protonation” &
intercalation of SWNTs
in 102% H2SO4
“Spaghetti”
In Oleum
V. A. Davis et. Al., Macromolecues 37, 154 (2004)
dried SWNT fiber
W.-F Hwang and Y. Wang
Prototype Wire - SWNT Fibers
• Producing Neat SWNT Fibers
• Dry-Spun from Oleum
• 6 to 14 Wt. % SWNT Dope
• Extruded as 50 µm Dia. Fibers
• 109 Tubes in Cross Section
• 100 Meters Long
Science 305, 1447-1450, 3 September 2004!!!
Ultimate Properties of Polymers
Staudinger Continuous Crystal Model
Perfect orientation
Perfect lateral order
Few chain end defects (HMW)
+
INTRINSIC CHAIN PROPERTIES
Hermann Staudinger, Die
Hochmolekularen
Organischen Verbindungen,
Berlin: Springer p.111 (1932)
SWNT Tensile Strength
Predicted tensile
strength of single-wall
nanotubes >100 GPa
Calculated strain-tofailure >30%
Measurements on
small bundles found
strength ~30-60 GPa
Yakobson, et al., Comp. Mat. Sci. 8, 341 (1997).
Quantum Wire on The Grid
Key Grid Benefits
• Eliminate Thermal Failures
• Reduce Wasted Power
• Reduce Urban R.O.W. Costs
• Enable Remote Generation
Grid Applications & Benefits
• Eliminate Thermal-Sag Failure: Now a $100B+ a year problem.
• Short-Distance AC: AQW could increase throughput up to ten-fold
without increasing losses while using only existing towers and
rights-of-way. Avoid new construction in congested urban areas –
estimated over $100M per mile.
• Medium-Distance AC: AQW could decrease resistive losses and
voltage drop ten-fold if amperage were not increased. This would
improve grid dynamics significantly in the range between 100 and
300 miles, where voltage stability limits deliverable power.
• Long-Distance HVDC: AQW could permit amperage throughput
ten fold or reduce losses ten-fold. New conventional lines cost
$1M to $2M per mile, plus about $250M per AC/DC converter
station.
• Remote Power: Could enable utilization of large-scale
renewables and remote nuclear.
NASA
Success
Stories
High Pressure CO (HiPCO) Process
Fe, Ni Catalysts
CO + CO
CO2 + SWNT + impurities
900-1200 C
10-40 atm
Continuous process
10-100’s g/day
Small diameters (0.7nm)
Company spin-off (CNI)
Rice Univ. Carbon Nanotechnologies, Inc.
& NASA
Buckytubes Offer Incredible Opportunities
Composites
Energy
Electrically conductive composites
– Wide range of conductivities
• Antistatic
• Electrostatic dissipation
• EMI/RFI shielding
– Bulk parts
– Transparent conductive coatings
– Anti-corrosion coatings
Reinforced composites
Tougher, stronger, stiffer, wear resistant
– Thermosets and thermoplastics
• Parts, coatings
– High performance fibers
– High performance ceramics
Thermally conductive composites
– Electronics packaging
– Industrial applications
Fuel cells
Supercapacitors and batteries
Photovoltaic cells
“Quantum Wires”
Electronics
Field emission
– Flat panel displays
– Back light units
– Electron device cathodes
Sensors
Printable electronics
Logic and memory devices
Interconnects
Roadblocks
• Vision without funding is hallucination.
• Da Hsuan Feng – UT Dallas
• Vision without hardware is delusion.
• Lockheed engineer
From the age of Space to the age of Medicine
New Energy Research Program
(Smalley’s Nickel & Dime Solution)
•
For FY06-FY10 collect 5 cents from every gallon of oil product
Invest the resultant > $10 Billion per year as additional funding in
frontier energy research distributed among DOE, NSF, NIST, NASA,
and DoD.
•
For the next 10 years collect 10 cents from every gallon;
invest the >$20 Billion per year in frontier energy research.
•
Devote a third of this money to New Energy Research Centers
located adjacent to major US Research Universities, especially Zip
Code 77005.
•
At worst this endeavor will create a cornucopia of new technologies
and new industries.
•
At best, we will solve the energy problem before 2020,
and thereby lay the basis for energy prosperity & peace worldwide.
Leadership
• President Bush – State of the Union
Address – Jan 31, 2006
– “America is addicted to oil”
– Replace oil imports from Middle East by
75% by 2025
• DOE Advanced Energy Initiative
22% increase in clean energy
research
–
–
–
–
Zero emission coal
Solar and wind
Clean, safe nuclear
Batteries, Hydrogen, ethanol
• A BIG change from the 2001
Cheney Energy Report – drill our
way to independence!
But…
• Are these ideas tough or aggressive enough?
• NO!
– Biofuels budget actually smaller than in FY06
– No market signal for more efficient vehicles
• Fuel economy standards – regulatory
– 40 mpg in 10 years saves 2.5M BOE/day
• Substantial gas tax – market mechanism
• Up to Congress to execute programs
– Incentives for alternate fuel production/vehicles
– Funding for research initiatives
The biggest single challenge for the next few decades:
ENERGY
for 1010 people
• At MINIMUM we need 10 Terawatts (150 M BOE/day)
from some new clean energy source by 2050
•
For worldwide energy prosperity and peace we need it to be cheap.
•
We simply can not do this with current technology.
•
We need Boys and Girls to enter Physical Science and Engineering as
they did after Sputnik.
•
Inspire in them a sense of MISSION
( BE A SCIENTIST --- SAVE THE WORLD )
• We need a bold new APOLLO PROGRAM
to find the NEW ENERGY TECHNOLOGY
PhD Degrees in Science and Engineering
25000
Asians citizens
All fields of Science &
Engineering
PhD per year
20000
15000
US citizens, all fields of Science
and Engineering, (excluding
psychology & social sciences)
10000
US citizens,
Physical Sciences and
Engineering only
5000
0
1985
1990
1995
2000
2005
Year
Source: Science and Engineering Indicators, National Science Board, 2002
By 2012, if current trends continue,
over 90% of all physical scientists and engineers in the world
will be Asians working in Asia.
Education
• American Competitiveness Initiative
– Double physical sciences research funding in ten
years (including nanotech, supercomputing,
alternative energy sources)
– Permanent R&D Tax Credit
– HS Math/Science teacher training (70,000) and add
30,000 M&S professional teachers
• YEA!
– But will Congress fund the initiatives?
– And will they sustain the funding??
2999
What Can YOU Do Now?
• Learn as much as possible
about energy
• Learn as much as possible
about nanotechnology
• Encourage kids to study science
and engineering!!
Reading Assignments
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Twilight in the Desert, Matthew R. Simmons
Winning the Oil Endgame, Amory Lovins
Beyond Oil: The View from Hubbert’s Peak, Kenneth S. Deffeyes
Out of Gas, Daniel Goodstein
The End of Oil, Paul Roberts
The Prize, Daniel Yergin
Hubbert’s Peak, Kenneth S. Deffeyes
The Hydrogen Economy, Jeremy Rifkin
Twenty Hydrogen Myths, Amory Lovins
(www.rmi.org)
Matt Simmons, web site: (www.simmons-intl.com)
M.I. Hoffert et. al., Science, 2002, 298, 981,
DOE BES Workshop Report on Hydrogen
(www.sc.doe.org/bes/hydrogen.pdf)
2003 State of the Future,
(www.stateofthefuture.org)
Nanotechnology and Energy, 2003 Report,
(www.cnst.rice.edu)
National Nanotechnology Program,
(www.nano.gov)