sergey l. bud’ko - iowa state universitycanfield.physics.iastate.edu/course/d14_slb.pdf ·...
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DilatometryPHY 590B S14
Sergey L. Bud’ko
Materials from the 2007 presentation of
George Schmiedeshoff, Occidental Collegewere heavily used
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Dilation: ∆V (or ∆L)
� T: thermal expansion: β = dln(V)/dT
H: magnetostriction: λ = ∆L(H)/L
Intensive Parameters:
� H: magnetostriction: λ = ∆L(H)/L
� P: compressibility: κ = dln(V)/dP
� E: electrostriction: ξ = ∆L(E)/L
� etc.
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A (very) Brief History
� Heron of Alexandria (0±100): Fire heats air, air expands, opening temple doors (first practical application…).
� Galileo (1600±7): Gas thermometer.� Galileo (1600±7): Gas thermometer.
� Fahrenheit (1714): Mercury-in-glass thermometer.
� Mie (1903): First microscopic model.
� Grüneisen (1908): β(T)/C(T) ~ constant.
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Phase Transition: TN
2nd Order Phase Transition, Ehrenfest Relation(s):
p
N2M
c
N2
CTV
p
T
∆
∆= c
d
d α
TbNi2Ge2
(Ising Antiferromagnet)
after gms et al. AIP Conf. Proc. 850, 1297 (2006). (LT24)
pc Cp ∆d
S
)(V
S
V
p
TM
N1
∆
∆≈
∆
∆=
∆
L
L
cd
d
1st Order Phase Transition, Clausius-Clapyeron Eq(s).:
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Paul Ehrenfest (1880-1933)
PhD from Vienna Technical University
1904 – married Tatyana Alexeyevna
Afanasieva – Russian mathematician
He was not merely the best teacher in our profession whom I have
ever known; he was also passionately preoccupied with the
development and destiny of men, especially his students. A. Einstein
Ehrenfest theorem
Ehrenfest paradox
Spinor
Classification of phase transitions
Ehrenfest-Tolman effect
Ehrenfest time
1907-1912 – St. Petersburg, Russia
(happiest days of his life)
1912-1933 - professor in Leiden
-------------------------------------------------
Depression…
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Grüneisen Theory (one energy scale: Uo)
.)(
)()(
ln
lnconst
TC
TTV
V
UM
o ==∂
∂−≡Γ
βκ
Γ−∝ VUo
)(ln TCV p
M∂
e.g.: If Uo = EF (ideal ) then:3
2=ΓIFG
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Grüneisen Theory (multiple energy scales: Ui each with Ci and Γi)
)()(
)(
TTC
TC
i
i
i
ii
Γ=
Γ
≡Γ∑
∑ e.g.: phonon, electron,
magnon, CEF, Kondo,
RKKY, etc.
)()(
)()( T
TC
TTV eff
p
Meff Γ=≡Γβ
κ
Examples: Simple metals: Γ~ 2 )ln(
*)ln(
3
2
Vd
mde +=Γ
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Example (Noble Metals):
After White & Collins, JLTP (1972).
Also: Barron, Collins & White, Adv. Phys. (1980).Also: Barron, Collins & White, Adv. Phys. (1980).
(Γlattice shown.)
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Example (Heavy Fermions):
After deVisser et al. (1990)
ΓHF(0)
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Dilatometers
� Mechanical (pushrod etc.)
� Optical (interferometer etc.).
� Electrical (Inductive, Capacitive, Strain Gauges).� Electrical (Inductive, Capacitive, Strain Gauges).
� Diffraction (X-ray, neutron).
� Others (absolute & differential).
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Technical Specifications
Furnaces (exchangeable):
RT ... 1200°C, RT ... 1600°C
Heating/Cooling rates:
0 ... 50 K/min
Sample holders: Fused Silica (max. 1100°C)
NEITZSCH – DIL 402
Alumina (max. 1600°C)
(user exchangeable)
Sample thermocouple:
type S (Pt/Pt10%Rh)
Measurement range:
500/5000 µm
Resolution: up to 8 nm/digit
Sample diameter ≈1 ... 12 mm
Sample length: 0 ... 50 mm
Atmospheres: oxid. (static, dynamic), inert
Electronics: integrated TASC 414/5
PC-Interface: USB
push-rod with inductive readout
(Ames Laboratory thermal analysis
facility in Wilhelm Hall)
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Optical dilatometer -
interferometer
nanometer resolution, commercially
available
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Strain gauges
Gauge factor,
GF =
[∆R/R]/[∆L/L] is [∆R/R]/[∆L/L] is
usually about 2
(for metal film
gauges)
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Strain gauges
GOOD:
- small, simple, cheap
- can be used with a rotator
∆ ∆ ∆
NOT SO GOOD:
- glue?
- calibration?- can measure ∆x, ∆y, ∆z in
one experiment
- can be used in pressure cells
- calibration?
- low T sensitivity?
- re-usability?
- dissipation at low temperatures?
- “large” samples
- effects of magnetic field?
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Piezoresistive canteliever dilatometer
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Piezoresistive canteliever dilatometer
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Piezoresistive canteliever dilatometer
α - U
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Piezoresistive canteliever dilatometer
GOOD:
- very small and compact
- can be used with a rotator
NOT SO GOOD:
- cell effects?
- calibration?- atomic resolution
- can be used in pulsed fields
- environmentally insensitive
- calibration?
- device to device reproducibility?
- re-usability?
- dissipation at low temperatures?
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fiber Bragg grating dilatometer
fiber Bragg grating
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fiber Bragg grating dilatometer
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fiber Bragg grating dilatometer
GdSb
5.4K
GdSi
4.8K
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fiber Bragg grating dilatometer
GOOD:
- intrinsically calibrated
- ~ 1A resolution
NOT SO GOOD:
- cell effects?
- only L || H- can be used in pulsed fields
- environmentally insensitive
- little dissipation at low T
- only L || H
- re-usability?
suggested to work in piston – cylinder pressure cell ???
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XRD dilatometry
Less accurate
Tedious/expensive
VERY useful for structural phase
transitions (gives structural
information)
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Capacitive Dilatometer (Cartoon)
DCapacitor
Plates
LCell
Body
Sample
D
AεC o=
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D3
Rev. Sci. Instrum. 77, 123907 (2006)
(cond-mat/0617396 has fewer typos…)
� Cell body: OHFC Cu.� Cell body: OHFC Cu.
� BeCu spring (c).
� Stycast 2850FT (h) and
Kapton (i) insulation.
� Sample (d).
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Calibration
� Use sample platform to push
against lower capacitor plate.
� Rotate sample platform (θ),
measure C.
Operating
Region
measure C.
� Aeff from slope (edge effects).
� Aeff = Ao to about 1%?!
� “Ideal” capacitive geometry.
� Consistent with estimates.
� CMAX >> C: no tilt correction.
CMAX ≥ 65 pF
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Cell Effect CuCuCellCellSampleSampledT
dL
LdT
dL
Lαα +−= ++
11
Much smaller cell effect, above ∼10K, using quartz (or sapphire?) instead of Cu for cell body. See, for example, Neumeier et al. (2005) and references therein.
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Tilt Correction
� If the capacitor plates are truly parallel then C → ∞ as D → 0.
� More realistically, if there is an angular misalignment, one can show that
C → CMAX as D → DSHORT (plates touch) and that
2
Pott & Schefzyk (1988).
� For our design, CMAX = 100 pF corresponds to an angular misalignment of about 0.1o.
� Tilt is not always bad: enhanced sensitivity is exploited in the design of Rotter et al. (1998).
+=
2
MAX
o
C
C1
C
AεD
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Kapton Bad (thanks to A. deVisser and Cy Opeil)
• Replace Kapton
washers with alumina.
• New cell effect scale.
• Investigating sapphire
washers.
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Torque Bad
� The dilatometer is sensitive to magnetic torque on the sample (induced moments, permanent moments, shape effects…).
� Manifests as irreproducible magnetostriction (for example).
� Best solution (so far…): glue sample to platform.
� Duco cement, GE varnish, N-grease…
� Low temperature only. Glue contributes above about 20 K.
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Hysteresis ~Bad
� Cell is very sensitive to thermal gradients: thermal hysteresis. But slope is unaffected if T changes slowly.changes slowly.
� Magnetic torque on induced eddy-currents: magnetic hysteresis. But symmetric hysteresis averages to “zero”:
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Quantum Oscillations
Can estimate uniaxial
pressure derivatives
of the extremal FS
cross-sections
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Lashley PRL Ce
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Bud’ko JPhysCondMat
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Correa, PRL
Extreme Conditions Group
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The Good & The Bad
� Small (scale up or down).
� Open architecture.
� Rotate in-situ (NHMFL/TLH).
� Cell effect (T ≥ 2K).
� Magnetic torque effects.
� Thermal and magnetic hysteresis.
� Vacuum, gas, or liquid
(magnetostriction only?).
� Sub-angstrom precision.
� Thermal contact to sample in
vacuum (T ≤ 100mK ?).
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Recommended:
� Book: Heat Capacity and Thermal Expansion at Low Temperatures, Barron & White, 1999.
� Collection of Review Articles: Thermal Expansion of Solids, v.I-4 of Cindas
Data Series on Material Properties, ed. by C.Y. Ho, 1998.
� Book (broad range of data on technical materials etc.): Experimental � Book (broad range of data on technical materials etc.): Experimental Techniques for Low Temperature Measurements, Ekin, 2006.
� Book: Magnetostriction: Theory and Applications of Magnetoelasticity, Etienne du Trémolet de Lacheisserie, 1993.
� Book: Thermal Expansion, Yates, 1972.
� Review Article: Barron, Collins, and White; Adv. Phys. 29, 609 (1980).
� Review Article: Chandrasekhar & Fawcett; Adv. Phys. 20, 775 (1971).
� …and references therein.