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Was the Taj Mahal originally an ancient Hindu temple?

Thanks for showing me more and more how primitive Hindus were.

Your bravado fails to impress. I just wanted to remove the mask of fake civility that you were trying to put on and show your real self. The same "civilization-hating" mindset that made the Islamic invaders destroy all vestiges of prosperity, art and learning wherever they went is dripping from your words. Keep it up for all to read!!!

akshardham delhi and akshardham gandhingar look, from the pictures, to be inspired by modernist and muslim architecture in layout. :azn:

Explain what you mean by Muslim architecture in layout? There are literally hundreds of temples in India with similar layouts from before the advent of Islam. Will you take my word for it or do I have to post pictures to prove even something as obvious as that?
 
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Your bravado fails to impress. I just wanted to remove the mask of fake civility that you were trying to put on and show your real self. The same "civilization-hating" mindset that made the Islamic invaders destroy all vestiges of prosperity, art and learning wherever they went is dripping from your words. Keep it up for all to read!!!
Islamic "Invaders" brought prosperity, art, and learning to Spain. Islamic "invaders" cleansed India of MOST primitive and barbaric practices, Islamic "invaders" made Cordoba, Baghdad and Cairo the education, health, and pretty much everything else capitals of the world.
I suggest, you ditch your Hinduvati teachers.
Islamic Golden Age - Wikipedia, the free encyclopedia
Because if it wasnt for Islam, you would've still be living in shit huts (which most of you do).

Your bravado fails to impress. I just wanted to remove the mask of fake civility that you were trying to put on and show your real self. The same "civilization-hating" mindset that made the Islamic invaders destroy all vestiges of prosperity, art and learning wherever they went is dripping from your words. Keep it up for all to read!!!



Explain what you mean by Muslim architecture in layout? There are literally hundreds of temples in India with similar layouts from before the advent of Islam. Will you take my word for it or do I have to post pictures to prove even something as obvious as that?
Show me Hindu temple layouts that are similar to Mosques.
 
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The same "civilization-hating" mindset that made the Islamic invaders destroy all vestiges of prosperity, art and learning wherever they went is dripping from your words. Keep it up for all to read!!!

Islamic civilization gave you both art and prosperity. Later colonialists stole the prosperity and you Indians have no sense of art. Independent India and its "culture" is the farthest thing from "art", lol!
 
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Yes in Hinduvati education Islamic architecture does not exist, infact Islam does not exist.
Islamic architecture - Wikipedia, the free encyclopedia
From the same page.
"What today is known as Islamic architecture owes its origin to similar structures already existing in Roman, Byzantine and Persian lands which the Muslims conquered in the 7th and 8th centuries."

BIG FAIL. :tsk:

Thanks for showing me more and more how primitive Hindus were.
ARE. :D
 
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Islamic civilization gave you both art and prosperity. Later colonialists stole the prosperity and you Indians have no sense of art. Independent India and its "culture" is the farthest thing from "art", lol!

Speaks the guy whose country does not have even a single monument recognized as having significant historic and architectural value.
 
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Why am i not surprised...

The Indian Hindus always make up lies to attack Islam and destroy anything to do with Islam.

I remember meeting a Hindu online who claimed Muslims killed at least 100 million Hindus in , i quote, "The world's worst holocaust!"

The Taj Mahal was built by a Muslim, no Hindu temple was destroyed, no Hindu temple was converted into a Mosque.

But i'll be waiting for the Hindu Nationalists to do what they did last time in Babri Masjid and destroy themselves and then kill some 1,000 Muslims while claiming that they're the victims and Muslims are evil.
 
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Yes, Pakistan has a metro -
Lahore-Metro-Bus-System-view-in-front-of-GC-University-overhead.jpg

metro9.jpg


Many more are under construction and planned; we only go for things we need - the need for one, came after migrants arrived and congested the cities and now a dozen are under construction. One Metro project is also included in CPEC. If you want to see the difference, i suggest you visit Pakistan.

China-Pakistan-Economic-Corridor-CPEC.jpg
How many brain cells did you destroyed when you compared a City Bus service with a METRO rail which we are making indigenously.

Free lesson .. this is a driver less metro
driverless_metro.jpg

article-2459728-18BD3D6E00000578-410_634x422.jpg


Mumbai Monorail
M_Id_443608_..jpg


And CPEC :lol: Naley sey dollar bahengey.

Islamic civilization gave you both art and prosperity. Later colonialists stole the prosperity and you Indians have no sense of art. Independent India and its "culture" is the farthest thing from "art", lol!
Islamic civilization gave you bengaladeshis every thing they could not produced by themselves f,it gave you your religion islam their customs but not for us Indians who are still 82% non muslims who follow native culture and religion and take pride in our own civilization thousands of years old.

why would be take pride in bastard architecture like taj which is a mix of persian,arab and indian hybrid when we have superior heritage of ours native to our land.

My ancestors made these thousand year before the arrival of islam before the arrival of paper and the age of inscriptions all these sites are now recognized by UN
Sanchi-Stupa-Elevation.jpg


Lion_Capital_at_Sarnath_1.jpg


@Maira La

what are the cultural achievement and contributions of your ancestors - I mean your religion is arab,your national anthem was written by a Hindu bengali - what is yours plz explain ?

IIT kanpur - Metallurgical prowess of indians before the advent of islam @Talwar e Pakistan do you have anything in pak before islamic era ?

THE CORROSION RESISTANT DELHI IRON PILLAR

ironpillar.jpg

The Iron Pillar at Delhi

The Delhi iron pillar is testimony to the high level of skill achieved by ancient Indian iron smiths in the extraction and processing of iron. The iron pillar at Delhi has attracted the attention of archaeologists and corrosion technologists as it has withstood corrosion for the last 1600 years. The several theories which have been proposed to explain its superior corrosion resistance can be broadly classified into two categories: the environmental and the material theories. Proponents of the environmental theories state that the mild climate of Delhi is responsible for the corrosion resistance of the Delhi iron pillar. It is known that the relative humidity at Delhi does not exceed 70% for significant periods of time in the year, which therefore results in very mild corrosion of the pillar.

On the other hand, several investigators have stressed the importance of the material of construction as the primary cause for the pillar's corrosion resistance. The ideas proposed in this regard are the relatively pure composition of the iron used, presence of Phosphorus (P) and absence of Sulphur/Magnesium in the iron, its slag-enveloped metal grain structure, and passivity enhancement in the presence of slag particles.

Other theories to explain the corrosion resistance are also to be found in the literature like the mass metal effect, initial exposure to an alkaline and ammoniacal environment, residual stresses resulting from the surface finishing operation, freedom from sulphur contamination both in the metal and in the air, and surface coatings provided to the pillar after manufacture (barffing and slag coating) and during use (coating with clarified butter).

That the material of construction may be the important factor in determining the corrosion resistance of ancient Indian iron is attested by the presence of ancient massive iron objects located in areas where the relative humidity is high for significant periods in the year (for example, the iron beams in the Surya temple at Konarak in coastal Orissa and the iron pillar at Mookambika temple at Kollur situated in the Kodachadri Hills on the western coast). It is, therefore, obvious that the ancient Indians, especially from the time of the Guptas (300-500 AD), produced iron that was capable of withstanding corrosion. This is primarily due to the high P content of the iron produced during these times. The addition of P was intentional as iron produced during earlier times does not show the presence of P.

To understand the precise reason for the corrosion resistance of the Delhi iron pillar, we analysed the composition of the rust on a Gupta period corrosion resistant iron clamp and also the rust on the Delhi iron pillar. Archaeometallurgical studies form a small component of our research activities. It is clear that referring to the Delhi iron pillar as rust-less is misleading as the iron pillar derives its corrosion resistance from the passive surface film (i.e. rust) that forms on the surface. We undertook a detailed rust analysis using modern sophisticated characterization techniques like Mössbauer spectroscopy and Fourier transform infrared spectroscopy (FTIR). We summarize below some of the exciting results of our study. The present study also provides valuable insight into the corrosion resistance of steels.

Microstructure

The microstructure of the iron of the Delhi iron pillar is typical of wrought iron. Iron was produced in ancient times by solid-state reduction of iron ore using charcoal and after the reduction process, the slag particles in iron were squeezed out by hammering. This invariably resulted in the presence of slag particles and unreduced iron oxide in the microstructure. We have earlier shown by theoretical mixed potential analysis and experimental potentiodynamic polarization studies (conducted on ancient iron) that the presence of slag particles could enhance passivity in these ancient irons containing P. However, the role of P in the passivation process was not understood. The characterization of the Delhi iron pillar rust has provided clear ideas about the passive film formation process on the Delhi iron pillar.

Rust Analysis

The FTIR spectrum proved the presence of g-FeOOH, a-FeOOH and d-FeOOH. The d-FeOOH was the major component of the rust as the peak was of relatively larger height compared to the others. An interesting result from the FTIR spectrum was that there was a distinct signal from the phase FePO4.2H2O and the shoulder from this phase was also identifiable. Therefore, the results of the FTIR study indicated that the constituents of the scale were g, aand d-FeOOH, in addition to a small amount of FePO4. In order to further understand the nature of the rust, the Mössbauer spectrum obtained from the rust in the transmission mode was analysed. The presence of g-FeOOH, a-FeOOH and d-FeOOH in superparamagnetic form was confirmed. The very fine particle size of these oxyhydroxides was also confirmed. The presence of iron phosphate was also confirmed. Finally, the rust was also composed of magnetite that was incorporated with some ions.

SURFACE FILM CAHARACTERISTICS

surface1.gif


surface2.gif

Process of Protective Rust Formation

The process of protective rust formation on the ancient Indian iron clamp can now be outlined based on the results presented above. The surface film characteristics of the Delhi iron pillar has been compared with that of mild steel in the accompanying figure. The rusting of normal mild steel and weathering steel is first addressed. When iron is exposed to the environment, the first oxides that form are the oxyhydroxides of Fe which are oxidized from Fe(II) complexes. Although several different allotropic modifications of the oxyhydroxides have been proposed to form on the surface of iron on initial exposure to the environment, there is firm evidence in the literature to suggest and prove that the first oxyhydroxide to form is g-FeOOH. After this is formed, a part of it begins to transform to another allotropic modification (a-FeOOH) and the rust at later times is composed of both these oxyhydroxides. These oxyhydroxides are not protective against corrosion and they readily crack allowing for ingress of oxygen and moisture to reach the metal surface and cause further corrosion. However, with time, a part of the FeOOH formed transforms to magnetic oxides of iron, which are much more protective than these oxyhydroxides. Mössbauer studies of rust formed on steel exposed to the environment clearly shows that Fe3O4 (more precisely to be called Fe3-xO4) forms first and this is later converted to g-Fe2O3. The formation of this magnetic oxide results in protection and the oxidation (corrosion) rates decrease once these oxides form on the surface from the oxyhydroxides. In addition to a- and g-FeOOH, there can be another oxyhydroxide d-FeOOH which can form on atmospheric exposure of iron.

It is interesting to note that d-FeOOH is generally amorphous in nature. In ordinary mild steels, this phase does not form as a continuous layer but rather in a discontinuous manner as it results due to dehydration-oxidation of the Fe(II) complexes. Therefore, the d-FeOOH that forms in ordinary mild steels is not protective in nature. However, it is possible for this d-FeOOH to form next to the metal surface as a continuous layer in which case the steel obtains corrosion resistance, as the oxyhydroxide is also amorphous in nature. The formation of d-FeOOH as a continuous layer next to the metal surface is catalysed by the presence of P (also Copper [Cu] and Chromium [Cr]) in the material. Moreover, the d-FeOOH is enriched with P and other elements that are added for improving atmospheric corrosion resistance like Cr and Cu. The presence of this amorphous layer is the reason for the excellent corrosion resistance of the so-called weathering steels.

In the case of ancient Indian iron, the atmospheric corrosion rate of the matrix material would be accelerated initially, in the presence of slag particles, leading to the enhancement of P concentration near the surface. Corrosion rate measurements (by Tafel extrapolation and weight loss methods) indicate that the short term corrosion rate of ancient Indian iron is an order of magnitude higher than that of 0.05%C mild steel in acidic environment while it is comparable in mildly alkaline environment. It must be noted that these measurements were obtained for complete immersion conditions, quite different from atmospheric exposure. Nevertheless, the initial corrosion of the matrix must lead to enrichment of P content near the surface. This is verified by compositional analysis of the metal next to the oxide which indicated enrichment of P in these regions. With the enhancement in the P concentration, the formation of d-FeOOH is catalysed and it should form as an amorphous compact layer next to the metal surface. Therefore, it appears that the presence of a significant amount of P is crucial to the corrosion resistance of the ancient Indian iron.

The process of passive film formation on the ancient Indian iron can be visualized as follows. Initially, the corrosion of the metal leads to the formation of a- and g-FeOOH. However, the presence of slag particles accelerates the corrosion of iron thereby enhancing the P concentration on the surface. This enhancement of P on the surface catalyses the formation of amorphous d-FeOOH as a compact layer next to the surface and this results in atmospheric corrosion resistance of the Delhi iron pillar. With time, conversion of this d-FeOOH to a stable form of iron oxide, i.e., magnetite, is possible. The magnetite could be doped with ions. This would further enhance the corrosion resistance of the surface film on the surface. The FTIR and Mössbauer spectra indicate the presence of iron phosphates. The presence of these phosphates would provide further corrosion resistance to the passive film by lowering ionic diffusion in the oxide and also by blocking the pores in the oxide. The golden hue of the pillar when viewed in certain orientations is due to the presence of iron phosphates. We hope to compositionally map the rust on the entire exposed surface of the pillar in the near future.

For more information contact:

Dr. R. Balasubramaniam

Department of Materials and Metallurgical Engineering

IIT Kanpur, Kanpur 208016

Telephone: (0512) 59 7089

e-mail: bala@iitk.ac.in

Iron Pillar
 
Last edited:
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From the same page.
"What today is known as Islamic architecture owes its origin to similar structures already existing in Roman, Byzantine and Persian lands which the Muslims conquered in the 7th and 8th centuries."

BIG FAIL. :tsk:


ARE. :D

Fact remains that all sophisticated art, Islamic or Byzantine or Martian, came to your land with the Muslim invasion. ;p

Speaks the guy whose country does not have even a single monument recognized as having significant historic and architectural value.

Because you reaped most of the benefits of the Muslim invasion being closer (than us) to the Middle East. ;)

My ancestors made these thousand year before the arrival of islam before the arrival of paper and the age of inscriptions all these sites are now recognized by UN


He calls Afghan-origin Aryans like Ashoka his ancestors. :lol:
@DeludedDalit, your opinions. :D
 
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Fact remains that all sophisticated art, Islamic or Byzantine or Martian, came to your land with the Muslim invasion. ;p



Because you reaped most of the benefits of the Muslim invasion being closer (than us) to the Middle East. ;)




He calls Afghan-origin Aryans like Ashoka his ancestors. :lol:
@DeludedDalit, your opinions. :D
I have jawmal rajput blood in my veins so i don't have to claim nothing and this is how jamwal looks my tall and martial bengladeshi friend.

220px-Vidhyut_&_Arhaan_at_the_launch_of_'Big_RTL_Thrill'_channel.jpg

Ranbir_Singh_Maharaja_of_Jammu_and_Kashmir.jpg


so again what are the achievements and contribution of your ancestors @Maira La i mean except for their handsome looks and martial character ?

I f you have any plz share us :lol:
 
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RSS should burn it down and build the biggest, baddest temple the world has ever seen. Jai Hind!
 
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How many brain cells did you destroyed when you compared a City Bus service with a METRO rail which we are making indigenously.

Free lesson .. this is a driver less metro
View attachment 276684
View attachment 276685

Mumbai Monorail
View attachment 276686

And CPEC :lol: Naley sey dollar bahengey.


Islamic civilization gave you bengaladeshis every thing they could not produced by themselves f,it gave you your religion islam their customs but not for us Indians who are still 82% non muslims who follow native culture and religion and take pride in our own civilization thousands of years old.

why would be take pride in bastard architecture like taj which is a mix of persian,arab and indian hybrid when we have superior heritage of ours native to our land.

My ancestors made these thousand year before the arrival of islam before the arrival of paper and the age of inscriptions all these sites are now recognized by UN
View attachment 276687

View attachment 276688

@Maira La

what are the cultural achievement and contributions of your ancestors - I mean your religion is arab,your national anthem was written by a Hindu bengali - what is yours plz explain ?

IIT kanpur - Metallurgical prowess of indians before the advent of islam @Talwar e Pakistan do you have anything in pak before islamic era ?

THE CORROSION RESISTANT DELHI IRON PILLAR

ironpillar.jpg

The Iron Pillar at Delhi

The Delhi iron pillar is testimony to the high level of skill achieved by ancient Indian iron smiths in the extraction and processing of iron. The iron pillar at Delhi has attracted the attention of archaeologists and corrosion technologists as it has withstood corrosion for the last 1600 years. The several theories which have been proposed to explain its superior corrosion resistance can be broadly classified into two categories: the environmental and the material theories. Proponents of the environmental theories state that the mild climate of Delhi is responsible for the corrosion resistance of the Delhi iron pillar. It is known that the relative humidity at Delhi does not exceed 70% for significant periods of time in the year, which therefore results in very mild corrosion of the pillar.

On the other hand, several investigators have stressed the importance of the material of construction as the primary cause for the pillar's corrosion resistance. The ideas proposed in this regard are the relatively pure composition of the iron used, presence of Phosphorus (P) and absence of Sulphur/Magnesium in the iron, its slag-enveloped metal grain structure, and passivity enhancement in the presence of slag particles.

Other theories to explain the corrosion resistance are also to be found in the literature like the mass metal effect, initial exposure to an alkaline and ammoniacal environment, residual stresses resulting from the surface finishing operation, freedom from sulphur contamination both in the metal and in the air, and surface coatings provided to the pillar after manufacture (barffing and slag coating) and during use (coating with clarified butter).

That the material of construction may be the important factor in determining the corrosion resistance of ancient Indian iron is attested by the presence of ancient massive iron objects located in areas where the relative humidity is high for significant periods in the year (for example, the iron beams in the Surya temple at Konarak in coastal Orissa and the iron pillar at Mookambika temple at Kollur situated in the Kodachadri Hills on the western coast). It is, therefore, obvious that the ancient Indians, especially from the time of the Guptas (300-500 AD), produced iron that was capable of withstanding corrosion. This is primarily due to the high P content of the iron produced during these times. The addition of P was intentional as iron produced during earlier times does not show the presence of P.

To understand the precise reason for the corrosion resistance of the Delhi iron pillar, we analysed the composition of the rust on a Gupta period corrosion resistant iron clamp and also the rust on the Delhi iron pillar. Archaeometallurgical studies form a small component of our research activities. It is clear that referring to the Delhi iron pillar as rust-less is misleading as the iron pillar derives its corrosion resistance from the passive surface film (i.e. rust) that forms on the surface. We undertook a detailed rust analysis using modern sophisticated characterization techniques like Mössbauer spectroscopy and Fourier transform infrared spectroscopy (FTIR). We summarize below some of the exciting results of our study. The present study also provides valuable insight into the corrosion resistance of steels.

Microstructure

The microstructure of the iron of the Delhi iron pillar is typical of wrought iron. Iron was produced in ancient times by solid-state reduction of iron ore using charcoal and after the reduction process, the slag particles in iron were squeezed out by hammering. This invariably resulted in the presence of slag particles and unreduced iron oxide in the microstructure. We have earlier shown by theoretical mixed potential analysis and experimental potentiodynamic polarization studies (conducted on ancient iron) that the presence of slag particles could enhance passivity in these ancient irons containing P. However, the role of P in the passivation process was not understood. The characterization of the Delhi iron pillar rust has provided clear ideas about the passive film formation process on the Delhi iron pillar.

Rust Analysis

The FTIR spectrum proved the presence of g-FeOOH, a-FeOOH and d-FeOOH. The d-FeOOH was the major component of the rust as the peak was of relatively larger height compared to the others. An interesting result from the FTIR spectrum was that there was a distinct signal from the phase FePO4.2H2O and the shoulder from this phase was also identifiable. Therefore, the results of the FTIR study indicated that the constituents of the scale were g, aand d-FeOOH, in addition to a small amount of FePO4. In order to further understand the nature of the rust, the Mössbauer spectrum obtained from the rust in the transmission mode was analysed. The presence of g-FeOOH, a-FeOOH and d-FeOOH in superparamagnetic form was confirmed. The very fine particle size of these oxyhydroxides was also confirmed. The presence of iron phosphate was also confirmed. Finally, the rust was also composed of magnetite that was incorporated with some ions.

SURFACE FILM CAHARACTERISTICS

surface1.gif


surface2.gif

Process of Protective Rust Formation

The process of protective rust formation on the ancient Indian iron clamp can now be outlined based on the results presented above. The surface film characteristics of the Delhi iron pillar has been compared with that of mild steel in the accompanying figure. The rusting of normal mild steel and weathering steel is first addressed. When iron is exposed to the environment, the first oxides that form are the oxyhydroxides of Fe which are oxidized from Fe(II) complexes. Although several different allotropic modifications of the oxyhydroxides have been proposed to form on the surface of iron on initial exposure to the environment, there is firm evidence in the literature to suggest and prove that the first oxyhydroxide to form is g-FeOOH. After this is formed, a part of it begins to transform to another allotropic modification (a-FeOOH) and the rust at later times is composed of both these oxyhydroxides. These oxyhydroxides are not protective against corrosion and they readily crack allowing for ingress of oxygen and moisture to reach the metal surface and cause further corrosion. However, with time, a part of the FeOOH formed transforms to magnetic oxides of iron, which are much more protective than these oxyhydroxides. Mössbauer studies of rust formed on steel exposed to the environment clearly shows that Fe3O4 (more precisely to be called Fe3-xO4) forms first and this is later converted to g-Fe2O3. The formation of this magnetic oxide results in protection and the oxidation (corrosion) rates decrease once these oxides form on the surface from the oxyhydroxides. In addition to a- and g-FeOOH, there can be another oxyhydroxide d-FeOOH which can form on atmospheric exposure of iron.

It is interesting to note that d-FeOOH is generally amorphous in nature. In ordinary mild steels, this phase does not form as a continuous layer but rather in a discontinuous manner as it results due to dehydration-oxidation of the Fe(II) complexes. Therefore, the d-FeOOH that forms in ordinary mild steels is not protective in nature. However, it is possible for this d-FeOOH to form next to the metal surface as a continuous layer in which case the steel obtains corrosion resistance, as the oxyhydroxide is also amorphous in nature. The formation of d-FeOOH as a continuous layer next to the metal surface is catalysed by the presence of P (also Copper [Cu] and Chromium [Cr]) in the material. Moreover, the d-FeOOH is enriched with P and other elements that are added for improving atmospheric corrosion resistance like Cr and Cu. The presence of this amorphous layer is the reason for the excellent corrosion resistance of the so-called weathering steels.

In the case of ancient Indian iron, the atmospheric corrosion rate of the matrix material would be accelerated initially, in the presence of slag particles, leading to the enhancement of P concentration near the surface. Corrosion rate measurements (by Tafel extrapolation and weight loss methods) indicate that the short term corrosion rate of ancient Indian iron is an order of magnitude higher than that of 0.05%C mild steel in acidic environment while it is comparable in mildly alkaline environment. It must be noted that these measurements were obtained for complete immersion conditions, quite different from atmospheric exposure. Nevertheless, the initial corrosion of the matrix must lead to enrichment of P content near the surface. This is verified by compositional analysis of the metal next to the oxide which indicated enrichment of P in these regions. With the enhancement in the P concentration, the formation of d-FeOOH is catalysed and it should form as an amorphous compact layer next to the metal surface. Therefore, it appears that the presence of a significant amount of P is crucial to the corrosion resistance of the ancient Indian iron.

The process of passive film formation on the ancient Indian iron can be visualized as follows. Initially, the corrosion of the metal leads to the formation of a- and g-FeOOH. However, the presence of slag particles accelerates the corrosion of iron thereby enhancing the P concentration on the surface. This enhancement of P on the surface catalyses the formation of amorphous d-FeOOH as a compact layer next to the surface and this results in atmospheric corrosion resistance of the Delhi iron pillar. With time, conversion of this d-FeOOH to a stable form of iron oxide, i.e., magnetite, is possible. The magnetite could be doped with ions. This would further enhance the corrosion resistance of the surface film on the surface. The FTIR and Mössbauer spectra indicate the presence of iron phosphates. The presence of these phosphates would provide further corrosion resistance to the passive film by lowering ionic diffusion in the oxide and also by blocking the pores in the oxide. The golden hue of the pillar when viewed in certain orientations is due to the presence of iron phosphates. We hope to compositionally map the rust on the entire exposed surface of the pillar in the near future.

For more information contact:

Dr. R. Balasubramaniam

Department of Materials and Metallurgical Engineering

IIT Kanpur, Kanpur 208016

Telephone: (0512) 59 7089

e-mail: bala@iitk.ac.in

Iron Pillar

:O A metro in India! India is the most sophisticated technologically advanced country. Jai Hind!

From the same page.
"What today is known as Islamic architecture owes its origin to similar structures already existing in Roman, Byzantine and Persian lands which the Muslims conquered in the 7th and 8th centuries."

BIG FAIL. :tsk:


ARE. :D
Everything has tributaries.
 
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Lol @ how hes ranting about his martial genealogy. And these guys say that we're the ones obsessing over it!

:mod:
 
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