Vibrating-sample magnetometer: Difference between revisions
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[[Image:VSM en.svg|thumb|VSM schematic]] |
[[Image:VSM en.svg|thumb|VSM schematic]] |
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[[Image:VSM.jpg|thumb|VSM setup]] |
[[Image:VSM.jpg|thumb|VSM setup]] |
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A '''vibrating |
A '''vibrating-sample magnetometer''' (VSM) (also referred to as a Foner magnetometer) is a scientific instrument that measures magnetic properties based on Faraday’s Law of Induction. Simon Foner at [[MIT Lincoln Laboratory]] invented VSM in 1955 and reported it in 1959.<ref>{{cite journal|last=Foner|first=Simon|year=1959|title=Versatile and Sensitive Vibrating-Sample Magnetometer|journal=Rev. Sci. Instrum.|volume=30|issue=7|pages=548–557|bibcode=1959RScI...30..548F|doi=10.1063/1.1716679|doi-access=free}}</ref> Also it was mentioned by G.W. Van Oosterhout<ref>{{Cite journal|last=Van Oosterhout|first=G.W.|date=1956|journal=Appl. Sci. Res.|volume=B6|pages=101}}</ref> and by P.J Flanders in 1956.<ref>{{Cite journal|last=Flanders|first=P.J.|date=1956|journal=IEEE Special Publication, Conference on Magnetism and Magnetic Materials|volume=T-91|pages=315–317}}</ref> A sample is first placed in a constant magnetic field and if the sample is magnetic it will align its magnetization with the external field. The [[Magnetic moment|magnetic dipole moment]] of the sample creates a magnetic field that changes as a function of time as the sample is moved up and down. This is typically done through the use of a [[piezoelectric]] material. The alternating magnetic field induces an electric field in the pickup coils of the VSM.<ref name=":0">{{Cite web|last=SWT Physics Department|title=Vibrating Sample Magnetometer|url=https://gato-docs.its.txstate.edu/jcr:7543b8ec-f619-49c3-888f-01c3ad13c7da/vsm.pdf}}</ref> The current is proportional to the magnetization of the sample - the greater the induced current, the greater the magnetization. As a result, typically a [[Hysteresis|hysteresis curve]] will be recorded<ref name=":1">{{Cite journal|last1=Lopez-Dominguez|first1=V.|last2=Quesada|first2=A.|last3=Guzmán-Mínguez|first3=J. C.|last4=Moreno|first4=L.|last5=Lere|first5=M.|last6=Spottorno|first6=J.|last7=Giacomone|first7=F.|last8=Fernández|first8=J. F.|last9=Hernando|first9=A.|last10=García|first10=M. A.|date=2018-03-01|title=A simple vibrating sample magnetometer for macroscopic samples|url=https://aip.scitation.org/doi/10.1063/1.5017708|journal=Review of Scientific Instruments|volume=89|issue=3|pages=034707|doi=10.1063/1.5017708|pmid=29604780 |bibcode=2018RScI...89c4707L |issn=0034-6748|hdl=10261/163494|hdl-access=free}}</ref> and from there the magnetic properties of the sample can be deduced. |
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The idea of vibrating sample came from D. O. Smith's<ref>{{Cite journal|last=Smith|first=D. O.|title=Development of a Vibrating‐Coil Magnetometer|journal=Rev. Sci. Instrum.|volume=27|issue=261|pages= |
The idea of vibrating sample came from D. O. Smith's<ref>{{Cite journal|last=Smith|first=D. O.|year=1956|title=Development of a Vibrating‐Coil Magnetometer|journal=Rev. Sci. Instrum.|volume=27|issue=261|pages=261–268|bibcode=1956RScI...27..261S|doi=10.1063/1.1715538|doi-access=free}}</ref> vibrating-coil [[magnetometer]]. |
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== Typical VSM overview == |
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=== Parts of a typical VSM setup === |
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[[File:VSM-schematic-highres.jpg|thumb|Simplified VSM schematic]] |
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* Actively cooled electromagnet/power supply |
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* Amplifier |
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* Control Chassis |
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* Meter |
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* Computer interface |
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* Sensor coils |
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* Vibration exciter with sample holder |
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* Hall probe (optional) |
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=== Sample Operating Procedure:<ref name=":0" /> === |
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# Mounting the sample in the sample holder |
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# Turning on the VSM system |
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# Run the computer software to initialize the system |
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# Calibrate the system |
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# Optimize the system for [[Magnetic moment|''M'']]<ref name=":0" /> |
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# Calibrate the Lock-In Amplifier |
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# Take measurements and record data |
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=== Conditions for VSM to be effective === |
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# Magnetic field must be strong enough to fully saturate the samples (or else inaccurate measurements will be taken) |
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# Magnetic field must be uniform across the sample space (otherwise the addition of field gradients<ref name=":1" /><ref name=":2">{{Cite journal|last1=Burgei|first1=Wesley|last2=Pechan|first2=Michael J.|last3=Jaeger|first3=Herbert|date=2003-07-10|title=A simple vibrating sample magnetometer for use in a materials physics course|url=https://aapt.scitation.org/doi/10.1119/1.1572149|journal=American Journal of Physics|volume=71|issue=8|pages=825–828|doi=10.1119/1.1572149|bibcode=2003AmJPh..71..825B |issn=0002-9505}}</ref> will induce force that alter the vibration once again leading to inaccurate results |
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==== Importance of pick-up coils ==== |
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These allow the VSM to maximize the induced signal, reduce the noise, give a wide saddle point, minimize the volume in between the sample and electromagnet to achieve a more uniform magnetic field at the sample space.<ref name=":1" /> The configuration of the coils can vary depending on the type of material being studied.<ref name=":1" /> |
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== Relation to Physics == |
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The VSM relies on [[Faraday's law of induction]], with the detection of the emf given by <math>\varepsilon = N{d \over dt}(BAcos\vartheta)</math>,<ref name=":2" /> where ''N'' is the number of wire turns, ''A'' is the area, and <math>\vartheta</math> the angle between the normal of the coil and the B field. However, ''N'' and ''A'' are often unnecessary if the VSM is properly calibrated.<ref name=":2" /> By varying the strength of the electromagnet through computer software, the external field is sweeped from high to low and back to high.<ref name=":2" /> Typically this is automated through a computer process and a cycle of data is printed out. The electromagnet is typically attached to a rotating base<ref name=":2" /> so as to allow the measurements be taken as a function of angle. The external field is applied parallel to the sample length<ref name=":2" /> and the aforementioned cycle prints out a [[Hysteresis|hysteresis loop]]. Then using known magnetization of the calibration material and wire volume the high field voltage signal can be converted into [[Centimetre–gram–second system of units|emu]] units - useful for analysis.<ref name=":2" /> |
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== Advantages and Disadvantages == |
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The precision and accuracy of VSM's are quite high even among other [[Magnetometer|magnetometers]] and can be on the order of ~ <math>\displaystyle 10^ {-6}</math> emu.<ref name=":1" /> VSM's further allow for a sample to be tested at varying angles with respect to its magnetization letting researchers minimize the effects of external influences.<ref name=":3">{{Cite web|date=2021-03-16|title=Interpretation of Vibrating Sample Magnetometer (VSM) analysis|url=http://www.analyzetest.com/index.php/2021/03/16/interpretation-of-vibrating-sample-magnetometer-vsm-analysis/|access-date=2021-05-14|website=analyzetest.com|language=en-GB}}</ref> However, VSM's are not well suited for determining the magnetization loop due to the demagnetizing effects incurred by the sample.<ref name=":3" /> VSM's further suffer from temperature dependence and cannot be used on fragile samples that cannot undergo acceleration (from the vibration).<ref name=":1" /><ref name=":2" /><ref name=":3" /> |
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==References== |
==References== |
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== See also == |
== See also == |
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* [[Magnetometer]] |
* [[Magnetometer]] |
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*[[Alternating (Field) Gradient Magnetometer (AFGM or AGM)]] |
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*[[SQUID magnetometers|SQUID Magnetometer]] |
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[[Category:American inventions]] |
[[Category:American inventions]] |
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[[Category:Measuring instruments]] |
[[Category:Measuring instruments]] |
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[[Category:Magnetometers]] |
[[Category:Magnetometers]] |
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{{electromagnetism-stub}} |
Latest revision as of 22:56, 26 September 2023
A vibrating-sample magnetometer (VSM) (also referred to as a Foner magnetometer) is a scientific instrument that measures magnetic properties based on Faraday’s Law of Induction. Simon Foner at MIT Lincoln Laboratory invented VSM in 1955 and reported it in 1959.[1] Also it was mentioned by G.W. Van Oosterhout[2] and by P.J Flanders in 1956.[3] A sample is first placed in a constant magnetic field and if the sample is magnetic it will align its magnetization with the external field. The magnetic dipole moment of the sample creates a magnetic field that changes as a function of time as the sample is moved up and down. This is typically done through the use of a piezoelectric material. The alternating magnetic field induces an electric field in the pickup coils of the VSM.[4] The current is proportional to the magnetization of the sample - the greater the induced current, the greater the magnetization. As a result, typically a hysteresis curve will be recorded[5] and from there the magnetic properties of the sample can be deduced.
The idea of vibrating sample came from D. O. Smith's[6] vibrating-coil magnetometer.
Typical VSM overview
[edit]Parts of a typical VSM setup
[edit]- Actively cooled electromagnet/power supply
- Amplifier
- Control Chassis
- Meter
- Computer interface
- Sensor coils
- Vibration exciter with sample holder
- Hall probe (optional)
- Mounting the sample in the sample holder
- Turning on the VSM system
- Run the computer software to initialize the system
- Calibrate the system
- Optimize the system for M[4]
- Calibrate the Lock-In Amplifier
- Take measurements and record data
Conditions for VSM to be effective
[edit]- Magnetic field must be strong enough to fully saturate the samples (or else inaccurate measurements will be taken)
- Magnetic field must be uniform across the sample space (otherwise the addition of field gradients[5][7] will induce force that alter the vibration once again leading to inaccurate results
Importance of pick-up coils
[edit]These allow the VSM to maximize the induced signal, reduce the noise, give a wide saddle point, minimize the volume in between the sample and electromagnet to achieve a more uniform magnetic field at the sample space.[5] The configuration of the coils can vary depending on the type of material being studied.[5]
Relation to Physics
[edit]The VSM relies on Faraday's law of induction, with the detection of the emf given by ,[7] where N is the number of wire turns, A is the area, and the angle between the normal of the coil and the B field. However, N and A are often unnecessary if the VSM is properly calibrated.[7] By varying the strength of the electromagnet through computer software, the external field is sweeped from high to low and back to high.[7] Typically this is automated through a computer process and a cycle of data is printed out. The electromagnet is typically attached to a rotating base[7] so as to allow the measurements be taken as a function of angle. The external field is applied parallel to the sample length[7] and the aforementioned cycle prints out a hysteresis loop. Then using known magnetization of the calibration material and wire volume the high field voltage signal can be converted into emu units - useful for analysis.[7]
Advantages and Disadvantages
[edit]The precision and accuracy of VSM's are quite high even among other magnetometers and can be on the order of ~ emu.[5] VSM's further allow for a sample to be tested at varying angles with respect to its magnetization letting researchers minimize the effects of external influences.[8] However, VSM's are not well suited for determining the magnetization loop due to the demagnetizing effects incurred by the sample.[8] VSM's further suffer from temperature dependence and cannot be used on fragile samples that cannot undergo acceleration (from the vibration).[5][7][8]
References
[edit]- ^ Foner, Simon (1959). "Versatile and Sensitive Vibrating-Sample Magnetometer". Rev. Sci. Instrum. 30 (7): 548–557. Bibcode:1959RScI...30..548F. doi:10.1063/1.1716679.
- ^ Van Oosterhout, G.W. (1956). Appl. Sci. Res. B6: 101.
{{cite journal}}
: Missing or empty|title=
(help) - ^ Flanders, P.J. (1956). IEEE Special Publication, Conference on Magnetism and Magnetic Materials. T-91: 315–317.
{{cite journal}}
: Missing or empty|title=
(help) - ^ a b c SWT Physics Department. "Vibrating Sample Magnetometer" (PDF).
- ^ a b c d e f Lopez-Dominguez, V.; Quesada, A.; Guzmán-Mínguez, J. C.; Moreno, L.; Lere, M.; Spottorno, J.; Giacomone, F.; Fernández, J. F.; Hernando, A.; García, M. A. (2018-03-01). "A simple vibrating sample magnetometer for macroscopic samples". Review of Scientific Instruments. 89 (3): 034707. Bibcode:2018RScI...89c4707L. doi:10.1063/1.5017708. hdl:10261/163494. ISSN 0034-6748. PMID 29604780.
- ^ Smith, D. O. (1956). "Development of a Vibrating‐Coil Magnetometer". Rev. Sci. Instrum. 27 (261): 261–268. Bibcode:1956RScI...27..261S. doi:10.1063/1.1715538.
- ^ a b c d e f g h Burgei, Wesley; Pechan, Michael J.; Jaeger, Herbert (2003-07-10). "A simple vibrating sample magnetometer for use in a materials physics course". American Journal of Physics. 71 (8): 825–828. Bibcode:2003AmJPh..71..825B. doi:10.1119/1.1572149. ISSN 0002-9505.
- ^ a b c "Interpretation of Vibrating Sample Magnetometer (VSM) analysis". analyzetest.com. 2021-03-16. Retrieved 2021-05-14.