Difference between revisions of "Stiff cantilever AFM"
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| − | + | [[File:QPlus sensor with zoomin.jpg|600px|thumb|right|A qPlus sensor (transpatent quartz) on a bigger holding plate (white ceramic) with a metallic tip attached. Note that this whole thing still needs to be mounted on a yet bigger Piezo-actuator-stage for nanopositioning in x,y,z directions.]] | |
| − | '''Stiff cantilever AFM''' generally known as '''(subatomically resolving) nc-AFM''' <br> | + | |
| + | [[File:B-doped graphene nanoribons.jpg|300px|thumb|right|An impressive example of what is possible to image with "stiff cantilever AFM" (and what is possible to synthesize, not the focus here). Here boron doped (sideways) atomically precise graphene nanoribbons. These images are taken from the 2015 paper [https://www.nature.com/articles/ncomms9098 "Atomically controlled substitutional boron-doping of graphene nanoribbons"] by Shigeki Kawai et al. (licensed CC-BY-SA-4.0 International). Note that such pictures are usually cherry picked and de-noised by filtering out high spacial frequencies.]] | ||
| + | |||
| + | '''Stiff cantilever AFM''' generally known as '''(subatomically resolving) nc-AFM''' (rarely FM-AFM) <br> | ||
is a form of [[scanning probe microscopy]] that probes forces rather than currents. | is a form of [[scanning probe microscopy]] that probes forces rather than currents. | ||
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Another difference between old and new: <br> | Another difference between old and new: <br> | ||
– old nc-AFM (an c-AFM) used deflection of a laser and a four quadrant photo-diode <br> | – old nc-AFM (an c-AFM) used deflection of a laser and a four quadrant photo-diode <br> | ||
| − | – new nc-AFM measures detuning of resonant frequency (frequency shift) <br> time can be measures especially precisely so this helps <br> | + | – new nc-AFM measures detuning of resonant frequency (frequency shift) <br> time can be measures especially precisely so this helps <br> '''Rarely it's called FM-AFM for frequency modulation.''' |
=== A horrible historic naming accident === | === A horrible historic naming accident === | ||
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Reason for why this page is called stiff cantilever AFM rather than nc-AFM. | Reason for why this page is called stiff cantilever AFM rather than nc-AFM. | ||
| − | There is also qPlus and kolibri, but these are brand names of specific stiff cantilever sensors. < | + | There is also qPlus and kolibri, but these are brand names of specific stiff cantilever sensors. <br> |
Not neutral names. More on these brands later. | Not neutral names. More on these brands later. | ||
| Line 52: | Line 55: | ||
Leaving only quantum mechanical simulations and comparing these teoretical predictions with experimental images. <br> | Leaving only quantum mechanical simulations and comparing these teoretical predictions with experimental images. <br> | ||
Good to do that for AFM too, but before that in case of AFM intuition can already help more. | Good to do that for AFM too, but before that in case of AFM intuition can already help more. | ||
| + | |||
| + | There is one new STM mode with picked up molecule that <br> | ||
| + | manages to achieve a similar resolution to stiff cantilever nc-AFM. <br> | ||
| + | {{wikitodo|Add more on that here.}} | ||
== Amplitudes, frequencies, parameters == | == Amplitudes, frequencies, parameters == | ||
| Line 59: | Line 66: | ||
Originally hacked together from quartz fork resonators from digital clocks. <br> | Originally hacked together from quartz fork resonators from digital clocks. <br> | ||
One side of the fork eventually tied to bulk mass for better results. <br> | One side of the fork eventually tied to bulk mass for better results. <br> | ||
| + | Oscillation amplitudes are typically slightly to strongly subatomic. <br> | ||
| − | + | '''Quantitative numbers form pentacene paper:''' | |
| + | * Apmplitude: 100pm down to 20pm | ||
| + | * Frequency: f0 = 23.165 kHz – Q = 50.000 (Meaning well more than 2s for ringing out after power-off.) | ||
| + | * Stiffness: 1800 N/m | ||
== Kolibri sensor == | == Kolibri sensor == | ||
Is is again orders of magbitude stiffer than the qPlus sensor. <br> | Is is again orders of magbitude stiffer than the qPlus sensor. <br> | ||
| − | As it can oscillate in | + | As it can oscillate in two directions it can detect sidewards forces too not just vertical ones. <br> |
As it is a newer younger design there may bot yet be as much community knowledge and user experience documentation around. <br> | As it is a newer younger design there may bot yet be as much community knowledge and user experience documentation around. <br> | ||
It seems to come withing a metal housing giving it a significant bigger size compared to qPlus. | It seems to come withing a metal housing giving it a significant bigger size compared to qPlus. | ||
| Line 74: | Line 85: | ||
* [[Scanning probe microscopy]] | * [[Scanning probe microscopy]] | ||
| + | * [[Snapback]] | ||
== External links == | == External links == | ||
| − | * Some relatively recent stiff cantilever nc-AFM work: <br>[https://www.youtube.com/watch?v=GK_gcG3sXSM MIT.nano Seminar Series: Leo Gross] | + | === Videos === |
| + | |||
| + | * 08m21s [https://www.youtube.com/watch?v=waXdLnX82gU Franz J Giessibl and the Q plus sensor: scanning probe microscopy 30 years on] | ||
| + | * 16m31s [https://youtu.be/9IGZA-fyQg8?si=UOtql6AZd__X3LF6 The genesis of the qPlus sensor - Focus Session Scanning Probe Microscopy with Quartz Sensors ~ by Franz J. Giessibl] | ||
| + | * Some relatively recent stiff cantilever nc-AFM work: <br>56m33s [https://www.youtube.com/watch?v=GK_gcG3sXSM MIT.nano Seminar Series: Leo Gross] | ||
=== Papers === | === Papers === | ||
| − | * 2009 – The Chemical Structure of a Molecule Resolved by Atomic Force Microscopy – by Leo Gross et.al. – [http://alpha.chem.umb.edu/chemistry/ch379/documents/pentacene.pdf (link to pdf)] | + | * 2020 – High resolution noncontact atomic force microscopy imaging with oxygen-terminated copper tips at 78 K – by Damla Yesilpinar et.al. – [https://pubs.rsc.org/en/content/articlehtml/2020/nr/c9nr10450j (link)] <br> – stiffer copper oxide tip at lN2 temperature (higher than usual), '''no bending image distortions that CO suffers from''' |
| + | * 2018 – The qPlus sensor, a powerful core for the atomic force microscope – by Franz J. Giessibl – [https://epub.uni-regensburg.de/50966/1/1.5052264.pdf (link to pdf)]<br> – a thorough overview paper by the inventor himself | ||
| + | * 2017 – High resolution SPM imaging of organic molecules with functionalized tips – by Pavel Jelínek – [https://www.columbia.edu/~jcc2161/documents/Jeninek_review_July_2017.pdf (link to pdf)]<br> – overview paper with many images | ||
| + | * 2015 – Atomic Resolution on Molecules with Functionalized Tips – by Leo Gross et.al. – [https://www.researchgate.net/publication/282314727_Atomic_Resolution_on_Molecules_with_Functionalized_Tips (via ResearchGate)]<br> – Figure1 shows sort of a "garden of molecules" on gold (Au) and bilayer(?) salt (NaCl). | ||
| + | * 2009 – The Chemical Structure of a Molecule Resolved by Atomic Force Microscopy – by Leo Gross et.al. – [http://alpha.chem.umb.edu/chemistry/ch379/documents/pentacene.pdf (link to pdf)]<br> – this was perhaps the watershed moment paper | ||
| + | |||
| + | '''Polyynes''' | ||
| + | * 2023 – On-surface synthesis of a polyynic carbon chain with ~40 alkyne units – by Wenze Gao et.al. <br>[https://www.researchsquare.com/article/rs-2639001/v1 prepring CC BY 4.0] ~ [https://www.researchgate.net/publication/368964600_On-surface_synthesis_of_a_polyynic_carbon_chain_with_40_alkyne_units preprint, direct preview on ResearchGate] | ||
| + | * {{wikitodo|Add other work on synthesis of polyyne rings on NaCl salt.}} | ||
| + | |||
| + | === Misc === | ||
| + | |||
| + | * Graphitic structures (especially including things like [https://en.wikipedia.org/wiki/Graphene_nanoribbon Graphene nanoribbons (wikipedia)] have become heavily studied by stiff cantilever nc-AFM. | ||
== Inventor & developers == | == Inventor & developers == | ||
Latest revision as of 14:30, 3 March 2024
Stiff cantilever AFM generally known as (subatomically resolving) nc-AFM (rarely FM-AFM)
is a form of scanning probe microscopy that probes forces rather than currents.
Contents
old nc-AFM ~vs~ new nc-AFM
Early AFM used soft cantilevers which led to problems that made subatomic resolution impossible.
The cantilevers where so soft that VdW forces, electrostatic forces, and whatever other forces present
led to a bi-stable snap to the surface.
– either these forces pressed the tip to the surface making it scratch over the surface quite roughly (contact mode)
– or the tip was so far away from the surface that subatomic resolution was not posible either (non-concact nc mode)
Noting in-between the two due to the bi-stable snap-to surface.
With the introduction of stiffer cantilevers the bi-stable snap could finally be avoided
and the tip could get close enough without snapping and crudely scratching such that that subatomic resolution with AFM could finally be achieved.
"contact mode" as in "crudely scratching over the surface with large long range press on forces" was no longer a thing.
Force measurement method
Another difference between old and new:
– old nc-AFM (an c-AFM) used deflection of a laser and a four quadrant photo-diode
– new nc-AFM measures detuning of resonant frequency (frequency shift)
time can be measures especially precisely so this helps
Rarely it's called FM-AFM for frequency modulation.
A horrible historic naming accident
Unfortunately the contact vs non-contact distinction (now with the bi-stable snap gone) makes no longer sense.
Rather more sensible would be to distinguish non-contact from contact by the switch from
attractive forces to repulsive forces. Roughly meaning the distance where one crosses under the vdW radii of atoms.
Now we often have a situation where we clearly are within the Pauli-repulsive-regime
(which is as much contact as one can possibly get) yet still the technique is named non-contact.
Reason for why this page is called stiff cantilever AFM rather than nc-AFM.
There is also qPlus and kolibri, but these are brand names of specific stiff cantilever sensors.
Not neutral names. More on these brands later.
STM ~vs~ stiff cantilever nc-AFM
STM was the oldest and first scanning probe microscopy technique that achived subatomic resolution.
AFM was for a long time not capable of comparable resolution due to the afore explained soft-cantilever-bistable-snap problem.
Once that problem was solved though resolution even exceeded the one of STM.
Actually it's rather that smaller electron structures can now be images that are usually easier to interpret by human intuition.
STM gets a great deal of resolution due to the fact that the
tunneling current steeply exponentially declines with distance
making only the foremost atom contribute by far the most.
Stiff cantilever AFM detects Pauli-repulsion-force which too declines sharply with distance.
STM is typically imaging farther away non-bonding orbitals which are bigger and
give less fine details about the shape of the molecule(s) under investigation.
Higher energy molecular orbitals often have node structures that are not really intuitive to interpret.
Leaving only quantum mechanical simulations and comparing these teoretical predictions with experimental images.
Good to do that for AFM too, but before that in case of AFM intuition can already help more.
There is one new STM mode with picked up molecule that
manages to achieve a similar resolution to stiff cantilever nc-AFM.
(wiki-TODO: Add more on that here.)
Amplitudes, frequencies, parameters
qPlus sensor
Originally hacked together from quartz fork resonators from digital clocks.
One side of the fork eventually tied to bulk mass for better results.
Oscillation amplitudes are typically slightly to strongly subatomic.
Quantitative numbers form pentacene paper:
- Apmplitude: 100pm down to 20pm
- Frequency: f0 = 23.165 kHz – Q = 50.000 (Meaning well more than 2s for ringing out after power-off.)
- Stiffness: 1800 N/m
Kolibri sensor
Is is again orders of magbitude stiffer than the qPlus sensor.
As it can oscillate in two directions it can detect sidewards forces too not just vertical ones.
As it is a newer younger design there may bot yet be as much community knowledge and user experience documentation around.
It seems to come withing a metal housing giving it a significant bigger size compared to qPlus.
(wiki-TODO: Add quantitative details.)
Related
External links
Videos
- 08m21s Franz J Giessibl and the Q plus sensor: scanning probe microscopy 30 years on
- 16m31s The genesis of the qPlus sensor - Focus Session Scanning Probe Microscopy with Quartz Sensors ~ by Franz J. Giessibl
- Some relatively recent stiff cantilever nc-AFM work:
56m33s MIT.nano Seminar Series: Leo Gross
Papers
- 2020 – High resolution noncontact atomic force microscopy imaging with oxygen-terminated copper tips at 78 K – by Damla Yesilpinar et.al. – (link)
– stiffer copper oxide tip at lN2 temperature (higher than usual), no bending image distortions that CO suffers from - 2018 – The qPlus sensor, a powerful core for the atomic force microscope – by Franz J. Giessibl – (link to pdf)
– a thorough overview paper by the inventor himself - 2017 – High resolution SPM imaging of organic molecules with functionalized tips – by Pavel Jelínek – (link to pdf)
– overview paper with many images - 2015 – Atomic Resolution on Molecules with Functionalized Tips – by Leo Gross et.al. – (via ResearchGate)
– Figure1 shows sort of a "garden of molecules" on gold (Au) and bilayer(?) salt (NaCl). - 2009 – The Chemical Structure of a Molecule Resolved by Atomic Force Microscopy – by Leo Gross et.al. – (link to pdf)
– this was perhaps the watershed moment paper
Polyynes
- 2023 – On-surface synthesis of a polyynic carbon chain with ~40 alkyne units – by Wenze Gao et.al.
prepring CC BY 4.0 ~ preprint, direct preview on ResearchGate - (wiki-TODO: Add other work on synthesis of polyyne rings on NaCl salt.)
Misc
- Graphitic structures (especially including things like Graphene nanoribbons (wikipedia) have become heavily studied by stiff cantilever nc-AFM.
Inventor & developers
- Franz Josef Giessibl (en)
- Franz Josef Gießibl (de)
- Leo Gross (Physiker) (de)
