Several Novel Ways of Storing and Manipulating Data
Author: David Saxton Ullery
The information in this posting may not be copied or used to create any technology without permission. Not-for-profit uses are permitted. Please comment and include any suggestions and questions that you may have. Thanks!
This article briefly outlines a few novel approaches that could potentially lead to dramatic increases in the amount of information that may be stored and manipulated at the nanometer scale, and shift the paradigm in the way information is traditionally manipulated and perceived. Some techniques demonstrate how a large amount of data could be stored directly as symbols or shapes, others outline possible alternative approaches to storing data by exploiting different properties of atomic elements that may offer insight into radically different approaches to the very problems that nanotechnology companies and researchers are working on today.
New approaches in thinking about exploiting previously unconsidered yet readily differentiating properties, opens the door to the thinking of the technologies that are researched and ultimately employed as a viable commercial product. Thus, the goal is that reading and pondering the concepts presented here will help trigger new ideas that will lead to much more economical approaches, new ways of thinking of computation, and ultimately newer, more powerful computational machines that do not necessarily follow the traditional Von Neumann architecture.
When examining future nanotechnologies for reading and writing information, storing data at a higher symbolic level of information other than only utilizing simple binary format should be examined as an alternative approach to the current standard architecture in today’s storage technologies. The approaches given here deal with the storing of information at the nanometer size, but are not directly exploiting quantum mechanical properties, nor do they depend on DNA or wetware. Instead, they depend upon both exploiting the unique properties of the atomic elements, and our increasingly sophisticated ability to move atoms to form any physical shape we desire, including directly storing symbols in their “natural” form. By purposefully positioning groups of atoms into various patterns, they may be interpreted in new and unique ways by the technology that reads, writes and manipulates the data.
Storing information may be enhanced in another way: More economical and useful ways of reading, writing, and manipulating data can be achieved by exploiting the informational differences inherent in different elements, along with the differences in a single element and its various isotopes. Different elements, isotopes, and molecules each have properties that could be exploited other than their quantum mechanical properties, and other common approaches that nanotechnology researchers are already examining. For example, every element has its own unique mass, atomic number, number of electrons, electromagnetic properties, chemical properties, size, shape, and so on. Shapes are especially interesting when configured in simple molecular structures, crystal structures or when atoms are physically moved in a purposeful manner atom-by-atom to form simple text or other symbols that can later be read and interpreted utilizing relatively simple algorithms.
Mixing and combining each of these and other ideas presented here and extrapolated upon by the knowledgeable reader would enhance all of these approaches in a synergistic manner. It opens up possibilities for alternatives to the traditional Von Neumann, binary-based architecture, yet does not force such a change.
Hydrogen (H) and Deuterium (D or ²H)
Alternative approaches for storing binary data using an element and its isotope.
Note: An element other than Hydrogen may be a better choice, but the concept is the same. However, Deuterium is very stable, not radioactive, and relatively plentiful in ocean water.
Since hydrogen and deuterium have their own unique atomic weight and emission spectrum, it should be eventually possible to detect tiny amounts of either, and use them to represent binary information. Another element/isotope pair should be considered, if there are known techniques for detection (reading) differences, and more efficient ways of switching states between the element and its related isotope. Other elements and their isotopes may have other properties, such as differing diameters that may be exploited more economically than hydrogen.
Here are a few ideas to consider:
- Use hydrogen, with mass number 1 to represent the zero (“0” or “off” or “no”) state.
- Use deuterium with mass number 2 to represent the one (“1” or “on” or “yes”) state.
- Read the values using mass spectrometry , infrared spectrometry, other non-destructuctive spectrometry methods utilizing much shorter wavelengths such as UV, or perhaps bounce a single photon off of each. A photon bounced off of a single hydrogen atom would behave differently than one bounced off of a single deuterium atom. Another approach may be to utilize a modified version of the technology of the scanning tunneling microscope STM, if it can be refined to the point where it could read the difference between an element and its isotope. Utilizing new forms of spectrometry (or other electromagnetic techniques), which use much higher frequencies than ultraviolet may someday utilized to detect size, position, mass, electromagnetic properties.
- To write data: Store the gases of each type and inject the atoms one by one into the bit containers. Another approach may be to find a way to push atoms into place, perhaps utilizing a modified, greatly shrunk down version of STM (see sections that follow for a bit more on this). Perhaps a neutron beam could be used in a novel way to convert H to D, thus “burning” ones into memory in a manner analogous to PROMs and EPROMs.
- Each tiny collection of atoms can be stored inside a single carbon buckyball, with each “bit” separated by an empty buckyball or by some other means, such as a tiny number of silicon atoms to separate each bit, such that the state of each atom or tiny cluster of atoms are not easily disturbed. Another approach may be to load up a nanotube or a column-like structure created using a few nanotubes. Each atom, or atom cluster would be fed into one end of the column, possibly followed by a separator element (consisting of a either a string or clump of one or more atoms such as silicon, or a buckyball), followed by another atom or atom cluster. Each atom or cluster would represent a zero or a one and could be read from one end of the column one at a time until the last atom is read… More on this in sections below.
This idea may be practical for memory storage of the more permanent kind, because writing may prove to be exceedingly slow for rapid computation. The ability to distinguish between different elements may be more practical for reading, but writing with multiple elements may prove to be difficult. A technique inspired by an ink jet printer could work – the valves would need to be extremely tiny – perhaps made from carbon nanotubes.
- Use any two elements that are easy to distinguish when only one or two or three atoms of each type is present. Binary numbers would be represented using one element as the zero, and the second element as the one value. Using a large atom such as lead to represent the “1″ value, and a much smaller atom, such as hydrogen to represent to the “0″ may prove beneficial.
- Use multiple element types, with each element representing a different value. The radix of the system would depend on the number of easily readable elements that can be stored into a tiny space using one, two, three or any tiny number of atoms each.
Using this scheme, hydrogen could represent a “zero”, helium a “one”, …, oxygen a “seven”, and so on (Atomic Number minus 1) for each element. The radix may be octal, decimal, base 36, or any base up to the number of elements used. Carbon, silicon and perhaps gold may need to be skipped since they are needed to construct the memory containers and may interfere with the readings. Rare elements may be avoided due to their cost or radioactive effects.
Similar to the two-element technique, it may be of benefit to select elements that vary in their atomic number (and mass) by large amounts rather than selecting closely related. Selecting elements from different groups within the periodic table may prove to be exploitable and therefore useful.
- Another binary alternative would be to stick to a single element. Use one atom, perhaps xenon to represent a “0″, and use two side-by-side atoms of the same element to represent a “1″. A variation on this theme could be to use zero atoms to represent “0″, and a cluster of one or more atoms to represent a “1″.
- Another approach is to use atoms of dramatically different size to represent differing values. The heavier elements are much larger than the lighter elements. Technologies may exploit these differences. Combining a few larger atoms together would increase these differences. Atoms may either be placed side-by-side or stacked one upon the other to produce a taller, nanometer-scale mountain. Using this approach, the data may be interpreted either digitally or analogically. Analogically if the mountains, or side-by-side, or some combination are made of varying elements with different sized atoms. One can imagine a nanometer sized head, not unlike a tiny record needle reading analog data, with an interface taking in the data; then, depending on the architecture of the future computing device, the context of the data, manipulating the data directly as analog data or digitizing the data. Multiple versions of digitized data are envisioned here; depending on the context once again: (a) interpret atomic-sized mountains over a certain threshold as a “one”, or (b) interpreting varying heights, or other features (total mass, …) as an analog value to be converted to a digitized value; (c) interpret the atomic stack of various element types as a stack of bits, (d) interpret data in any manner where it is economic to read, write and manipulate
For any approach selected, it may turn out that only elements that are solid at or near room temperature are practical, thus ruling out all of the gases and liquids. Alternatively, simple molecules, such as NaCl, or other salts could be used, if there are better techniques for reading and/or writing molecules. Even H2O – water molecules could be employed if the data is kept cool enough – erasing this data would obviously be very simple.
Reading and Writing the Atoms for Each Alternative Technique
In either the element/isotope or the multi-element concept, one could “write” the atoms (or molecules) into a nanometer sized tube that is transparent enough for electrons or photons to bounce off of each atom, one at a time. It may be necessary to use one element (may need to be several atoms long to insulate the properties of each “bit”) as a type of tag or marker to separate the information atoms, especially if more than one of each element is needed.
As an alternative to bouncing electrons or photons off of each atom, a reading head and writing head could be created using a technology based on already existing scanning tunneling microscopes (STM). This approach may be particularly useful in the single-element approach where a pattern (0 or 1; 1 or 2 groups) are used.
Exploiting the unique particle velocities or resonance frequencies generated of elements or molecules of different mass may be combined with other technologies to measure differences between atoms or molecules to read the atoms from different elements. Acoustic and electromagnetic waves may be utilized to generate frequencies to induce large amplitude vibrations within a system of atoms lined up in patterns.
The nanotube structure could be used to keep the atoms or atom clusters (molecules) in place, like so many beads on a string, or more like a line of different color peas inside a transparent straw. The design close up may resemble chicken wire. It may not be a completed tube, but merely a trough or rain drain-like structure that is “U” shaped from the end instead of “O” shaped.
Rows of these tube or trough-like nanotube structures could be connected together to create a two dimensional matrix, or a single, very long structure could be wound up into a disc, like a CD or DVD disc and read from the inside out.
It is interesting to note here, regardless of the selected alternative, that an STM reader could conceivably read large chunks of atoms at a time, projecting different shapes that could then be decompressed by shape-recognition software into standard bits, bytes, or any other form, including the original form. A string of ones and zeros physically represented by atoms or small clusters of atoms would form unique shapes due to the distribution of mass, electromagnetic, and other properties. To read these shapes as chunks may require the trough to have a certain amount of “wiggle room” so that the atoms may not form a completely straight line. Different elements or molecules may be readily coaxed into specific shapes by subjecting them to different electric charges, magnetic fields, chemicals, or simply by squeezing them into or through other nano-sized machines or templates (like a tiny cookie cutter).
Nanometer Scaled Symbolic Writing
The following outlines the concept of storing data more directly as high-level text or other types of high-level symbols, thus effectively compressing much more information into bit-sized areas for simple text messages. In some cases, depending on current state-of-the-art, an “atom” may be replaced with “a cluster of atoms”, or “a molecule” or “a cluster of molecules”, but the concept is such that in any alternative, the real estate used must be substantially smaller than the current space required for a single bit on today’s storage systems. Given that a nanometer is 10 to the -9th meters, a typical atom’s ranges from about 0.1 to 0.5 nanometer, and today’s memory chips are storing bits at the 45-nanometer level, it seems we have some room to work with.
Let us examine some potential ways we might represent information at the atomic level.
- Store text, including entire computer programs using ordinary text, but write the text at the tiniest possible size. Remember the I.B.M. Logo? All three letters contain a total of 35 xenon atoms (atomic number 54). Each atom is spaced at what looks like one or two atom widths apart on average. According to the article from the link above: “In 1989, IBM scientist Don Eigler was surprised to learn that in addition to using an STM to look at tiny things he could also use it like a pair of tweezers, to move things as small as a single atom.” Suppose that the text could be crushed down to use no more than 8 atoms per character – the same number of bits used in today’s binary ASCII code, yet still be kept in the same general shape as the actual letters, or perhaps some new, more compressed, yet easily recognizable set of shapes. It may be easier for a technology to read the entire glob as a shape than it would be to read each atom as a single bit.
- Use lines of atoms of different lengths to represent different values. Example: “.”=0, “-”=1, “–”=2, “—”=3; where each “-” is one, two or three atoms in length…perhaps larger clumps would be needed or more economical. Molecules could replace atoms, if kept very tiny (whatever is the least number of atoms or smallest size molecule that can be detected at high speed). This is simply a variation of “1″ above, but keeping each shape more or less as a line, however the length of each symbol would grow with the number of characters represented. If we kept the number of symbols small, say to 10 or less, then the longest line would be only 10 atoms wide. One could imagine building a code based on combining various symbols without necessarily resorting to a number system. It would be constructed like a kind of short hand.
- Use different shapes to increase the symbol set, without increasing the number of atoms. Example: “+”, “^” could be represented using four and three atoms respectively. This is really no different than option “1″, but could be interpreted as a variation on option two or a hybrid between 1 and two where the atoms are allowed to occupy more than a single row.
- Use marker symbols to distinguish the representation of any of the above representations to create a hybrid. Marker symbols may be actual text-like or at least shapes or combination of shapes not unlike XML tags, or they may be atoms of a different elements or molecules as discussed in previous sections. A processor configured to read multiple symbolic representations may have the ability to reconfigure its actual hardware, or load different algorithms into its memory. It may be that the actual processor is of a traditional silicon/binary type with a suitable interface that acts like a connector/adapter/translator/mapper between the computer and the storage. Alternatively, it may be that the entire computer is constructed to directly manipulate these symbols or to at least readily convert them in a much more tightly coupled manner than a traditional computer would be able to do.
- The symbols used may not resemble any of the symbols familiar to us like those on our keyboard. It may be more convenient to exploit the shapes that clusters of atoms tend to form when combined together. Crystals are one example, but they tend to have several variations. The point is that the shapes need to be as easy as possible to construct, be stable, yet be consistent and deterministic. If a given element, with a limited number of atoms forms the same set of shapes, it may be possible to filter them so that they can be used to represent a set of symbols.
- Utilize binary or some other radix where needed, or where more generalize information is needed. Binary data may still be stored as a shape rather than utilizing the atoms or clusters of atoms as simple zero-one bits. More is discussed about this below.
- A two-dimensional photograph could be compressed down as a simple black and white photo (atom/no atom), or a color photograph (1,2, or 3 atoms; where one=”red”, two=”blue” and three=”yellow”). Simple markers could be used to (A) tag that it is photo information, and (B) tag the next row of an array, or simply tag the actual “bit” length of each “row” of pixels – in other words to mark out how many patterns or “1″ “2″ and “3″ would be needed. Note however, that three or even four characters can be represented in binary, using just two bits (atoms): “00″,”01″, “10″, “11″.
Once again, a modified scanning tunneling microscope (STM) technology can be used to write and read the data using either technique or any hybrid combination.
Rather than storing information as bits, the information is stored and read directly at a symbolic level. Simple software algorithms would be used to translate the characters and shapes to be used and interpreted as needed.
For example: a Java program may be stored as source code using a tiny number of atoms to represent each character. The java program would be read using the STM-based reader, then translated (decompressed) into byte code and run on a conventional computer, if desired. Alternatively, an entire CPU architecture could be build around the new storage technique that directly manipulates the stored symbols. Literal XML tags could be used, if desired to mark code and data sections.
The multiple techniques presented in this section and the previous section could be combined. Use the one/two atom pair technique (to store binary code. Separate the code with special tags (atom-by-atom XML or otherwise).
Perhaps the text could eventually be shoved into super long, nanotube-based structures and wound up into a disk storing up trillions of times the data currently stored on today’s high definition DVDs. This would be similar to the device describe in the previous sections.
In scenarios where memory reads could be relatively slow, then it would make sense to pack more data, using less atoms to represent the data. The link above shows that using current technology, at least 3 letters can be written and read using an STM.
Once the concept of reading symbols sinks in, it becomes apparent that the most general form of information can be represented in binary, and it may seem that information could be compressed better if data is always represented this way, but the concept of utilizing symbol recognition could enhance this most general case. Using just two atoms (or groups or molecules), we can arrange them in the following ways:
( 1 ) “- “ [just one atom followed by no atom, or “10”] ,
( 2 ) “–” [two atoms next to each other, or “11”],
( 3 ) ” -” [no atom, followed by one atom, or “01”]
( 4 ) “= “ [two atoms, one above the other, with no atom next to it, or “1010”],
( 5 ) “\ “ [two atoms at an angle, down and to the left, or “1001”]
( 6 ) ” /” [two atoms at an angle, down and to the right, or “0110”]
( 7 ) “_ “ [no atoms on top an one atom below, or “0010”]
( 8 ) ” _” [no atom on top, and one atom below and to the right, or “0001″
Of course, in theory, there could be up to four atoms within the given space, thus allowing for 15 values, but the reader and writer must both be able to distinguish all of those patterns in the same tiny space. It may be the case where multiple atoms packed closely together will not retain a stable pattern.
Once the technology reaches the level where a single atom could be read, then pure binary representation may be the best technique in 100% of the cases, but using shape recognition may still be the best way to interpret the information. It may be more practical to limit the number of atoms within a given space and interpret the limited number of shapes within that space as a particular value. It would work in a manner not unlike using braille for the blind. If all of the available space can be filled in with every combination, that is great, but we can still exploit the concept without completely utilizing every conceivable combination and permutation.
Unusual Processing NanoMachines That Eat Data
Another variation on reading of data could be a of the destructive kind. Read the atoms by grabbing them off of their storage surface and literally pass the data into the processor. A machine that directly works with shapes instead of bits could process different symbols by filtering them into different locations. Using lined up symbols like those described in “2” above could direct the data based on each symbol’s length. Longer symbols could not enter shorter slots. Data contextualized as numeric or alphabetical could quickly be sorted by length (spaghetti sort), addition would be fairly straight forward (add the lengths).
In another context, the data could be interpreted as an algorithm for constructing multiple copies of another nano-mechanical machine. The symbols may consist of various length rods, gears, levers and pulleys as the “data” section; intermingled with short instruction sets. The processor may be cleverly enough designed to be capable of understanding how to manufacture thousands or millions of tiny machines. The symbol “6” followed by the symbol for a gear could indicate that the machine is to grab the next six gears out of the gear repository or instruct another part of the machined to build six gears built to the size of the “data” gear, and perhaps to use the same element in doing so (the data gear may be made out of carbon or gold, for example).
Utilizing the direct literal “grabbing” of data, the mass of the “bits” could be exploited by a machine designed to take advantage of data in this context. For example, data could be directly sorted or added together by mass; larger atoms or more massive molecules could be filtered so that the computing machine would be reconfigured to perform different operations. Suppose nano-sized gears could only be turned by an atomic mass of greater than or equal to 18 = 2 oxygen or 18 hydrogen atoms.
Grabbing data may be as straight forward as pushing “end of file” atoms into one end of a nanotube, thus allowing the program to push out the other end in a FIFO manner, down into a slot where the calculating machine sits.
We can utilize shape recognition at the atomic or molecular level to store binary information. If a single element is utilized, then the shape alone could represent an arbitrary value.
We can utilize shape recognition at the atomic or molecular level to store information directly as symbols, potentially packing more information into the same tiny space where a single bit may ordinarily be stored. This same technology could then be utilized to ultimately reduce the information back down to the binary level, but using the same techniques and technology that we use to detect shapes. It may turn out that multiple shapes are more readily recognized than directly using the atom (or smallest practical “unit”) in the more straight forward way of simply looking at “atom = 1″, “no atom = 0″, or “two atoms = 1 and one atom = 0″ in a linear manner.
We could potentially use different elements or their isotopes to store more information into a single bit without resorting to quantum computer effects, but by exploiting the different spectrum and/or mass, and possibly other differences among the elements. If combinations of elements are used, then atomic number or electromagnetic properties could be utilized to give a single physical shape more than one value. Two star shapes with different mass could represent two distinct values, for example. Two squares, made with the same element but with differing numbers of atoms or with differing spaces between the atoms potentially could be exploited.
We could potentially use different elements as markers or tags, not unlike tags utilized in XML. We could literally create XML tags just like the famous IBM logo was created. Alternatively, we could employ the idea of packing different elements or molecules between sections of data to be interpreted as a change in context.
We could use nanotube to stuff atoms into – to be read one at a time, or potentially read as chunks with the unique shapes later to be decompressed. It is even conceivable that a highly sophisticated machine could interpret and manipulate the chunks and shapes directly. The shapes of each chunk may be exploited in the design of the processor itself. Taken further, the tags or markers could be utilized to directly modify the processor.
We could use a plane surface to read shapes or combine this concept with the nanotube or buckyball concept mentioned earlier.
Processing data at the symbolic level may open up new and unique approaches to computing. The processing techniques could be simulated using ordinary, binary computers by building a virtual machine designed to manipulate symbols. The simulations would be used as a discovery process so that alternative architectures may be explored.
Finally, we may discover these ideas to not be good ideas at all, yet it may toggle the mind of someone else in science, art or music in some yet unknown way. Perhaps it is on the right track, but requires another approach that some else may come up with. Perhaps someone in a completely different field may look at this posting, sleep on it, and come up with another novel idea that is directly useful or creates yet another tangent. A fractal-like graph may result, pointing toward some great idea to solve some totally unrelated problem. The final result may be four or five or six or one hundred people down the chain – it may loop back around to me…
In the futuristic, on line, open source, science fiction novel “Upgrade 01A“, computers that utilize nanotechnology (some perhaps similar to what is briefly outlined here), some based on DNA, some based on quantum computers, others based on yet unheard of technologies, and some hybrids, are common place. Many tiny, microscopic computers and robots are integrated inside the bodies, brains, and clothing of the main characters. Thus, the characters’ physical abilities, intelligence, and life expectancy are greatly enhanced or upgraded. New devices implanted in a person’s brain are often referred to as “upgrades” and may include a model number that is traditionally denoted as a hexadecimal number. Computers are integrated into virtually every device and object of value. Please read part one and enjoy…
↑Top of Page↑ [Home] [Back to More Posts]
© All rights reserved, with the exceptions given on the home page. In short, feel free to use this material in any public URL with “.com”, or “.edu” domains for non-profit purposes. Please link back to whatever you reference.