I'm a dental nurse studying for my radiography qualification and have been struggling with understanding some areas of physics. Just wanted to say how amazing this video is, and I'll be watching on repeat and taking revision notes from this ( aswell as my textbook of course!). Thanks so much
In general ionisation means that an electron has been knocked out of an atom so that the atom is positively charged (ionized). Excitation means that the electron has been pushed up to a higher energy level (but still within the atom). The atom still has all its electrons and is not ionised. But the excited electron will soon fall back to a lower energy level emitting a photon.
Hi Jake - Thanks for your kind comments. I would be very happy to do the videos you suggest but I'm afraid I cant do them in time for Monday and probably not for another week or so. But good luck in your exam. I hope it goes well.
Yes. There is the braking radiation. But the main X rays come from high energy electrons knocking electrons from the inner shells of the anode. Outer shell electrons can then fall down the energy level to take the space vacated by the electron. This fall in energy is released as a photon - in this case in the X ray wavelength range.
My A Level Physics revision playlist has videos on Gravitation and Electricity, both of which refer to the inverse square law for Newton's or Coulomb's laws.
Good simple explanation and useful practical/clinical tips. Just to correct one mistake DrPhysicsA in your explanation from 14:15 to 14:35, when x-rays strike the radiographic film it is blackened, not whitened or grayed. That is why the shadow of bone on the radiograph appears white or grey because the x-rays are attenuated by the dense bone. However the soft tissues do not stop the x-rays at all from penetrating hence that part of the radiographic film appears black.
Where x-rays are produced as a result of electrons falling from outer energy levels to inner energy levels then this will be a constant process because energy is constantly being given to the atom to enable electrons to jump up to the higher energy levels in the first place.
Ionisation is where the energy given to the electron (eg from a photon) is sufficient to kick the electron completely out of the atom. The atom therefore has a residual positive charge. Excitation is where the photon gives enough energy to promote the electron to a higher energy level but still in the atom.
Hi I'm an A Level student and I have my AQA unit 5 exam on Monday, I find your videos so helpful. I learn more after watching them than I've learnt in all my lessons on those topics. If you have time would you be able to do some videos on other Medical Physics topics? such as the eye, ear, and heart? This is the stuff on my syllabus, if you could make a video on anything on here it would be extremely helpful!
Thanks. In my efforts to show where the X rays would penetrate and where they wouldn't I didn't properly cover their impact on the photographic plate. I've added an annotation.
Thankyou for the great video, it really did help! I am just slightly confused with the graph. You said that were the minimum wavelength are seen high energy x-rays occur. On the y-axis there is intensity, so does that mean the x-rays produced on the left side of the graph have an high energy but low intensity?
watched a ton of videos on x rays and sorry to say their are a ton of really bad Physics teachers out there, BUT your videos was awesome. Thank you I HIGHLY recommend.
No i searched for linear attenuation coefficient for X-ray but didn't get what I was looking for. But with attenuation coefficient i got it on wikipedia. Thanks Sir.
My videos certainly cover the OCR syllabus but they all so cover material in the AQA and Edexcel syllabus as well as some material in the Cambridge syllabus.
Thanks. HIgh and low energy photons will enter the body but low energy X rays will be wholly absorbed and not appear on the photographic plate. High energy will be attenuated but will still pass thro the body. So low energy X rays add to the overall dose but for no worthwhile effect.
Thank you very much DrPhysicsA. It was very beneficial for me to learn physics in conceptual way. I think it would have been better if we can get your video in HD too.
Tungsten has a high electron density and, when hit by the electrons coming from the cathode, emits a characteristic x-ray, in that the waves have a high enough frequency and therefore, enough energy to penetrate the aluminium plate covering the tube and thus, enough energy to penetrate the bone etc to reach the lead (less penetrable material to absorb the photons)...
You can add this correction as tag to your video for those minutes. [Reference: 'Nature of the radiographic image', pg. 3, Essentials of Dental Radiography and Radiology by Eric Whaites, 4th edition.]
I'm stumped on that one I'm afraid. I guess the answer has to do with the technology and which element best provides the Xrays which are most suitable for medical purposes. But I could be wrong. Anyone else know?
that last part got me thinking about orthographic projection. is that grating essentially creating an ortho look? if it does then, is it possible to create an ortho-lens in that manner to attach to a regular (visible-light) camera? btw, great video, thank you!
I just have a few questions, does the rotor part of the anode also rotate along with the disc? Which part of the mechanism actually controls the tube current, is it the tube part of the cathode or the thermionic filament? Also, the anode is the positive part but does this refer specifically to the disc of the anode or the rotor that's positive to attract the electrons?
Your welcome. I understand this but I assume there's a deeper reason to this. I'm guessing that low energy photons 'frequency' causes some interaction (resonace?) with molecules more easily that high 'frequency' does. Or is it just explain cause high freuquency photons pass due to having more energy(as some being absorbed but even few which pass leave a mark on plate) or even some other way? Thanks a lot!
Hello awesome video that complemented my textbook and brought life to the application section of my physics course. Is there a video about the attenuation of X-rays? Like where we use the formula to fine resultant intensity and so on? thanks
it would be good if you can explain in further details of the use of the materials alongside with the description of the x-ray tube , e.g.why is tungsten used. Just a suggestion to your future videos (maybe?)
What would happen if an incident electron didn't make a head on collision with one of the tungsten electrons but got very close? would it excite the tungsten electron and that would then emit a photon when it falls back down to its original energy level? if so, would it emit x-rays?
Dear DrPhysicsA: From the video, are you meaning the x-ray generation from the acceleration of electron beams is equivalent to that from the energy transition of the outer shell back into the inner shell. They are of the same, but different pictures. right ?
I am sort of confused. So the braking radiation and inner shell electron transition are two different mechanisms. The latter is the usual way to generate x-ray. Right? and does the electron acceleration inside the CRT(cathode ray tube) create some long-wavelength x-ray or just the ultra-violet radiation ?
+DrPhysicsA Dear Dr. I got one question. At 14:00 why you draw the X Rays emerging from Anode not straight lines but around 15:00 you draw straight lines that are emerging from anode. Is this because the samples are bone and soft tissues respectively? If yes , but how do the X Rays know whats the sample. So Can you explain both cases considering the same straight lines emerging? Thanks
isent it something to do with the distance between nuclei (diameter of nuclei 10 to the -10) being smaller then the low energy photons (E inversely proportional to Wavelength) so a photon with wavelength greater then 10 to the -10 will be absorbed by the atoms...
Dear DrPhysicsA, this is a great presentation. But something worrying me ,The lead gratings at 17.00, will also be shown in the Films? that will obstruct with the image of interest. ? kindly clarify
Thank you so much! Very well X-plained!
I see what you did there.
You explain so clearly in 18 minutes what took my teacher 50 minutes to explain and I still didn't get it. Thank you for an excellent explanation!
Thank you for your very kind comments. I'm very glad that it helped.
I'm a dental nurse studying for my radiography qualification and have been struggling with understanding some areas of physics. Just wanted to say how amazing this video is, and I'll be watching on repeat and taking revision notes from this ( aswell as my textbook of course!). Thanks so much
In general ionisation means that an electron has been knocked out of an atom so that the atom is positively charged (ionized). Excitation means that the electron has been pushed up to a higher energy level (but still within the atom). The atom still has all its electrons and is not ionised. But the excited electron will soon fall back to a lower energy level emitting a photon.
Hi Jake - Thanks for your kind comments. I would be very happy to do the videos you suggest but I'm afraid I cant do them in time for Monday and probably not for another week or so. But good luck in your exam. I hope it goes well.
Yes. There is the braking radiation. But the main X rays come from high energy electrons knocking electrons from the inner shells of the anode. Outer shell electrons can then fall down the energy level to take the space vacated by the electron. This fall in energy is released as a photon - in this case in the X ray wavelength range.
This is so amazing! These explanations follow the exact contents which are in the application booklet, also maintaining the serial. Loved it!
My A Level Physics revision playlist has videos on Gravitation and Electricity, both of which refer to the inverse square law for Newton's or Coulomb's laws.
Good simple explanation and useful practical/clinical tips. Just to correct one mistake DrPhysicsA in your explanation from 14:15 to 14:35, when x-rays strike the radiographic film it is blackened, not whitened or grayed. That is why the shadow of bone on the radiograph appears white or grey because the x-rays are attenuated by the dense bone. However the soft tissues do not stop the x-rays at all from penetrating hence that part of the radiographic film appears black.
Amazing explanation clearly and easy to understanding. Thank You so much
Thanks. Nice to know its recommended by your professor.
Perfect presentation,perfect demonestration
I am so happy to watch this
DrPhysicsA you are simply incredible
Where x-rays are produced as a result of electrons falling from outer energy levels to inner energy levels then this will be a constant process because energy is constantly being given to the atom to enable electrons to jump up to the higher energy levels in the first place.
Ionisation is where the energy given to the electron (eg from a photon) is sufficient to kick the electron completely out of the atom. The atom therefore has a residual positive charge. Excitation is where the photon gives enough energy to promote the electron to a higher energy level but still in the atom.
finally I understood how x-rays work thank you so much for this amazing video
this is ridiculously helpful. thank you so much for these videos!
i learned so much in your video! biomedical imaging is making sense now! thank you!
U, my friend, are a life saver
Thank Dr for uploaded this kind of professional lecture. It help me a lot.
Excellent video, has a wonderfully concise explanation.
WOW! This is the best explanation of X-Rays...!! Thank you!
I have my physics exam in a fee hours and I'm just watching this rn , lovely , but thank you sir for explaining everything in such a superb way !
Hi
I'm an A Level student and I have my AQA unit 5 exam on Monday, I find your videos so helpful. I learn more after watching them than I've learnt in all my lessons on those topics.
If you have time would you be able to do some videos on other Medical Physics topics? such as the eye, ear, and heart?
This is the stuff on my syllabus, if you could make a video on anything on here it would be extremely helpful!
How kind. Glad it was of some help. All good wishes for your studies.
Glad I found these in time for my G485 exam, really good explanation.
Feels like im getting a physics lecture off bruce forsyth :)
The best x-ray explanation ever, THE BEST !
Thanks anyway!
Most of your videos cover most of the stuff, and have really made a difference for me.
Thanks again
I have the same exam on Monday - thank you so much for these videos!
Good luck for Monday everyone! :)
Thanks. In my efforts to show where the X rays would penetrate and where they wouldn't I didn't properly cover their impact on the photographic plate. I've added an annotation.
Very very good one . just love it.
Great video!! Thank you so much for your explanation... All of your vids are all well-explained.
My ideal teacher of physics
Thankyou for the great video, it really did help!
I am just slightly confused with the graph. You said that were the minimum wavelength are seen high energy x-rays occur. On the y-axis there is intensity, so does that mean the x-rays produced on the left side of the graph have an high energy but low intensity?
Best comprehensive explanation I've found. Thanks so much!! Just one critique; video quality ;)
Vicky Medrano its was made in 2012 what do you expect?
watched a ton of videos on x rays and sorry to say their are a ton of really bad Physics teachers out there, BUT your videos was awesome. Thank you I HIGHLY recommend.
Beautiful explanation!
This is really useful! This is also GCSE physics by the way, you may choose to change the key terms so others can find it!
hardly.....
adil m It's in my syllabus?
James Lavender what board?
By hardly I mean that in GCSE there is hardly any depth.
Edexcel, and I agree- although it is easier to answer a question when you understand something rather than just knowing that it happens.
Wonderful explanation! This was super helpful!
That was a really good explanation of xrays! Thank you very much!
Excellent. Thank you!
Thanks. Nice to have it explained.
No i searched for linear attenuation coefficient for X-ray but didn't get what I was looking for. But with attenuation coefficient i got it on wikipedia. Thanks Sir.
My videos certainly cover the OCR syllabus but they all so cover material in the AQA and Edexcel syllabus as well as some material in the Cambridge syllabus.
Precise and perfect
You did a nice job! I think it will be help to review this when I study.
Thanks. HIgh and low energy photons will enter the body but low energy X rays will be wholly absorbed and not appear on the photographic plate. High energy will be attenuated but will still pass thro the body. So low energy X rays add to the overall dose but for no worthwhile effect.
Thank you very much DrPhysicsA. It was very beneficial for me to learn physics in conceptual way. I think it would have been better if we can get your video in HD too.
Tungsten has a high electron density and, when hit by the electrons coming from the cathode, emits a characteristic x-ray, in that the waves have a high enough frequency and therefore, enough energy to penetrate the aluminium plate covering the tube and thus, enough energy to penetrate the bone etc to reach the lead (less penetrable material to absorb the photons)...
Very well explained! Thank you!
My professor recommanded your video. thanks for great video.
Ahhh everything makes so much more sense now! A big thank you to you!!!! :)
Excellent! thank you so much for your explanation!
You can add this correction as tag to your video for those minutes. [Reference: 'Nature of the radiographic image', pg. 3, Essentials of Dental Radiography and Radiology by Eric Whaites, 4th edition.]
Aweeeeeeeeeeeesomeeeeeeeeeeeeeeeeee videeoooooo ....
u r the best physics teacher :) (y)
subscribed..!
Awesome! I'm marking level 3 Btech course work and I'm a biologist...... Thank you!!!!!
This was very helpful thanks for the video
You explained really well.
This is fantastic - thank you so much!!!!!
I'm stumped on that one I'm afraid. I guess the answer has to do with the technology and which element best provides the Xrays which are most suitable for medical purposes. But I could be wrong. Anyone else know?
Thanks! You explained a lot!
Thnx for providing knowledge to people like us
Excellent commentary.
A excellent lesson! Thank you!
Best explanation.. love it
Thank you professor, it's a great lecture.
Helpful video. Thanks.
I suggest you use high resolution camera, and a better lighting.
Awesome explanation! Thank you :)
that last part got me thinking about orthographic projection. is that grating essentially creating an ortho look? if it does then, is it possible to create an ortho-lens in that manner to attach to a regular (visible-light) camera?
btw, great video, thank you!
very nicely explained. Thanks a lot :)
I like this video, it helps a lot. Good Job, thanks...
Excellent video...
This is very useful, thank you.
The video sound is pretty good, beyond my imagination
Which A Level syllabus are you following?
Thank you. Your voice is amazing
I just have a few questions, does the rotor part of the anode also rotate along with the disc? Which part of the mechanism actually controls the tube current, is it the tube part of the cathode or the thermionic filament? Also, the anode is the positive part but does this refer specifically to the disc of the anode or the rotor that's positive to attract the electrons?
Your welcome.
I understand this but I assume there's a deeper reason to this. I'm guessing that low energy photons 'frequency' causes some interaction (resonace?) with molecules more easily that high 'frequency' does. Or is it just explain cause high freuquency photons pass due to having more energy(as some being absorbed but even few which pass leave a mark on plate) or even some other way?
Thanks a lot!
Wow. Great job.
thnx atlast i understood it ur a nice mentor
Thank you so much, this is really helpful!!!
Hello awesome video that complemented my textbook and brought life to the application section of my physics course. Is there a video about the attenuation of X-rays? Like where we use the formula to fine resultant intensity and so on? thanks
brilliant stuff
Thank you very much!!
Have you looked at "Attenuation coefficient" on Wikipedia?
it would be good if you can explain in further details of the use of the materials alongside with the description of the x-ray tube , e.g.why is tungsten used. Just a suggestion to your future videos (maybe?)
What would happen if an incident electron didn't make a head on collision with one of the tungsten electrons but got very close? would it excite the tungsten electron and that would then emit a photon when it falls back down to its original energy level? if so, would it emit x-rays?
Dear DrPhysicsA:
From the video, are you meaning the x-ray generation from the acceleration of electron beams is equivalent to that from the energy transition of the outer shell back into the inner shell. They are of the same, but different pictures. right ?
I am sort of confused. So the braking radiation and inner shell electron transition are two different mechanisms. The latter is the usual way to generate x-ray. Right? and does the electron acceleration inside the CRT(cathode ray tube) create some long-wavelength x-ray or just the ultra-violet radiation ?
Great video, but what about X-ray attenuation and image intensifiers, also contrast media and CAT scans are in the textbook
what happens to the electron when it delivers all its energy to radiation. zero kinetic energy implies it comes to a stop. But how is that possible?
great ...
دەستت خۆش بێت
the man doesn't have arms ._.
otherwise a really good video! helped me a lot!
They are maybe amputated and he went to the doctor for a follow up
+DrPhysicsA
Dear Dr. I got one question. At 14:00 why you draw the X Rays emerging from Anode not straight lines but around 15:00 you draw straight lines that are emerging from anode. Is this because the samples are bone and soft tissues respectively? If yes , but how do the X Rays know whats the sample. So Can you explain both cases considering the same straight lines emerging? Thanks
isent it something to do with the distance between nuclei (diameter of nuclei 10 to the -10) being smaller then the low energy photons (E inversely proportional to Wavelength) so a photon with wavelength greater then 10 to the -10 will be absorbed by the atoms...
Thank you so much this helped me a lot :)
Dear DrPhysicsA, this is a great presentation. But something worrying me ,The lead gratings at 17.00, will also be shown in the Films? that will obstruct with the image of interest. ? kindly clarify
The lead gratings are long but sufficiently thin
You're the man.
Very very nice video
But why high energy photons penetrate body but low frequenzy ones not?
Thank you!