Yet Another Cycling Forum
General Category => The Knowledge => OT Knowledge => Topic started by: hubner on 30 August, 2019, 12:27:12 am
-
If a magnet sticks to a piece of metal , would that prove the metal is not titanium?
-
Yes. It's also the reason my wife can get through airport scanners with two metal hips.
-
I have a '90s MTB with the handlebars marked as titanium, but a magnet sticks to them... >:(
-
Titanium bikes arent pure titanium though are they. They are an alloy of titanium and vanadium (and maybe aluminium sometimes). Isn't vanadium very magnetic? Its used in superconducting magnets.
-
A few Ti bike frames and components were made of commercially pure Ti in the old days but most modern frames are made from 3/2.5 or 6/4 Ti which have pretty low percentages of alloying materials.
-
A quick search into the properties of my Ti bike shows a vanadium content of 2.5%. I have no idea if vanadium is magnetic (I thought it was only ferrous materials that are??).
I'll put a magnet to the frame and see what happens. I know it's Ti because it has a sticker on it saying so ;D.
-
A quick search into the properties of my Ti bike shows a vanadium content of 2.5%. I have no idea if vanadium is magnetic (I thought it was only ferrous materials that are??).
I'll put a magnet to the frame and see what happens. I know it's Ti because it has a sticker on it saying so ;D.
Iron, Cobalt and Nickel are strongly magnetic
According to wikipedia Vanadium alloy is used in "super conducting magnets"
-
Vanadium is paramagnetic at room temperature, so will not stick to a magnet. A lot of vanadium used in alloys is ferro-vanadium, so can contain an amount of iron, but is more likely used when alloying steel. A Ti/Vn alloy used for bike frames is unlikely to show any magnetic attraction, since any Fe will only be present in trace amounts. Disclaimer - I don't know this for certain and haven't studied magnetism since about 25 years.
-
simple answer;
Magnets don't 'stick to' titanium alloys (as found in bike parts). This is very easy to demonstrate to yourself by wafting a magnet at some new, genuine Ti parts.
There are lots of plated steel bike parts which are 'titanium coloured'. Often the owners live in blissful ignorance until their 'titanium parts' go rusty....
The more nuanced answer is that there can be a weak attraction between some materials and magnets; for example most nominally austenitic stainless steels contain a small percentage of ferrite and a weak attraction can be felt; this attraction is about 1/10th or 1/20th as strong as the attraction of the same magnet to a piece of ordinary steel; the magnet won't 'stick' per se and at most, commercial Ti alloys won't even exhibit this amount of magnetism. Thus if the magnet 'sticks to' a piece of 'titanium' then it ain't titanium, simple as that.
cheers
-
A lot of stainless steel isn't very magnetic.
I have a lump of it (6mm thick, ~140mm long) in my wrist. Not even disk magnets stick to my arm or show any sign of being attracted to it.
-
A lot of stainless steel isn't very magnetic...
It varies, hence my mention of 'nominally austenitic'. There are ferritic, martensitic, austenitic , precipitation hardening and duplex grades, amongst others; they all have different magnetic properties.
FWIW very few nominally austenitic grades contain absolutely no ferrite whatsoever, but it would take a very strong magnet or a sensitive instrument to pick up a small percentage if it is buried in your arm.
cheers
-
I'll put a magnet to the frame and see what happens. I know it's Ti because it has a sticker on it saying so ;D.
If it's unpainted, ridden in the rain, and not rusty, chances are that it's not a ferrous material! Okay, it does not prove that it is titanium.
A
-
The more nuanced answer is that there can be a weak attraction between some materials and magnets; for example most nominally austenitic stainless steels contain a small percentage of ferrite and a weak attraction can be felt; this attraction is about 1/10th or 1/20th as strong as the attraction of the same magnet to a piece of ordinary steel
Where's that picture...
(http://www.ductilebiscuit.net/gallery_albums/random/IMG_1253.sized.jpg)
-
Titanium bikes arent pure titanium though are they. They are an alloy of titanium and vanadium (and maybe aluminium sometimes). Isn't vanadium very magnetic? Its used in superconducting magnets.
Couple of things about superconducting magnets. With (very) rare exceptions, you're going to be needing liquid helium to be getting to the temperature at which it is a superconductor. Even the superconducting materials with the highest temps still need cooling with liquid nitrogen. I suspect you're not using cryogenic liquids in your experimentation ;)
Without looking it up - most high-temp superconductors are compounds - not metal alloys. I.e. it might contain 'vanadium' in the same way that rust contains iron. I.e. it's not in its metallic form and isn't magnetic (in a superconducting material - without being cooled to like ~4 K)
As has been said - if it's ferro-magnetic - it's not titanium.
-
the superconducting materials I've seen looked like a lump of black beeswax and required liquid nitrogen
-
A lot of stainless steel isn't very magnetic.
I have a lump of it (6mm thick, ~140mm long) in my wrist. Not even disk magnets stick to my arm or show any sign of being attracted to it.
[OT]
Some certainly is!
I tend to play with cutlery whilst awaiting restaurant meals and some knife handles are sufficiently magnetic to lift other cutlery...
-
The more nuanced answer is that there can be a weak attraction between some materials and magnets; for example most nominally austenitic stainless steels contain a small percentage of ferrite and a weak attraction can be felt; this attraction is about 1/10th or 1/20th as strong as the attraction of the same magnet to a piece of ordinary steel
Where's that picture...
(http://www.ductilebiscuit.net/gallery_albums/random/IMG_1253.sized.jpg)
Nope. The position of the other hand and the curving of the palm are all "magicians sleight of hand" alarms.
-
the superconducting materials I've seen looked like a lump of black beeswax and required liquid nitrogen
Liquid helium mostly, only the very top-end ones have a superconducting temperature within the reach of liquid N2.
The superconducting magnets we use in our NMR spectrometers (that's the same as MRI in hospitals) have a liquid helium core jacket and then a larger outer liquid nitrogen jacket to keep the liquid helium cold!
-
The more nuanced answer is that there can be a weak attraction between some materials and magnets; for example most nominally austenitic stainless steels contain a small percentage of ferrite and a weak attraction can be felt; this attraction is about 1/10th or 1/20th as strong as the attraction of the same magnet to a piece of ordinary steel
Where's that picture...
(http://www.ductilebiscuit.net/gallery_albums/random/IMG_1253.sized.jpg)
Nope. The position of the other hand and the curving of the palm are all "magicians sleight of hand" alarms.
The palm's curved due to general lack of bones, and because barakta's wrist is fused in that position by the pins the magnet is sticking to. Her other hand's in that position to prevent wobble because her shoulder's out of joint to hold her left hand up like that. The magnet doesn't stick strongly enough to the ostensibly stainless steel pins to allow you to do the really cool magnet hanging upside down photo, and that's a bastard strong magnet.
-
I do not know how long barajas wrist has been fused but titanium wrist fusion plates are relatively new. If it is more than 5 years ago it is a steel alloy with steel screws. The only wrist fusion plate for donkeys years was made by AO foundation and being swiss-German steel was the thing.
-
It's a pair of late-1980s pins, not a plate, and as far as we know it's a stainless steel (that's presumably paramagnetic). We didn't expect the magnet to do anything, and were really impressed when it just barely stuck.