Data remanence: Wikis

  
  

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Data remanence is the residual representation of data that has been in some way nominally erased or removed. This residue may be due to data being left intact by a nominal delete operation, or through physical properties of the storage medium. Data remanence may make inadvertent disclosure of sensitive information possible, should the storage media be released into an uncontrolled environment (e.g., thrown in the trash, or given to a third party).

Over time, various techniques have been developed to counter data remanence. Depending on the effectiveness and intent, they are often classified as either clearing or purging/sanitizing. Specific methods include overwriting, degaussing, encryption, and physical destruction.

Contents

Causes

Many operating systems, file managers, and other software provide a facility where a file is not immediately deleted when the user requests that action. Instead, the file is moved to a holding area, to allow the user to easily revert a mistake.

Even when an explicit deleted file retention facility is not provided or when the user does not use it, most computers do not actually remove the contents of a file when it is deleted. Instead, they simply remove the file's entry from the file system directory, because this requires less work and is therefore usually faster. The contents of the file—the actual data—remain on the storage medium. The data will remain there until the operating system reuses the space for new data. In some systems, enough filesystem metadata is also left behind to enable easy undeletion by commonly available utility software. Even when undelete has become impossible, the data, until it has been overwritten, can be read by software that reads disk sectors directly. Computer forensics often employs such software.

Likewise, reformatting, repartitioning or reimaging a system is not always guaranteed to write to every area of the disk, though all will cause the disk to appear empty or, in the case of reimaging, empty except for the files present in the image, to most software.

Finally, even when the storage medium is overwritten, physical properties of the medium may make it possible to recover the previous contents using laboratory techniques.

Countermeasures

There are three levels commonly recognized for eliminating remnant data:

Clearing

Clearing is the removal of sensitive data from storage devices in such a way that there is assurance that the data may not be reconstructed using normal system functions or software file/data recovery utilities. The data may still be recoverable, but not without special laboratory techniques.[1]

Clearing is typically an administrative protection against accidental disclosure within an organization. For example, before a hard drive is re-used within an organization, its contents may be cleared to prevent their accidental disclosure to the next user.

Purging

Purging or sanitizing is the removal of sensitive data from a system or storage device with the intent that the data can not be reconstructed by any known technique. Purging, proportional to the sensitivity of the data, is generally done before releasing media outside of control, such as before discarding old media, or moving media to a computer with different security requirements.

Destruction

The storage device is physically destroyed by incineration, melting, shredding, pulverizing, drilling or other means that completely prevent data recovery.

Specific methods

Overwriting

A common method used to counter data remanence is to overwrite the storage medium with new data. This is often called wiping or shredding a file or disk. Because such methods can often be implemented in software alone, and may be able to selectively target only part of a medium, it is a popular, low-cost option for some applications. Overwriting is generally an acceptable method of clearing, as long as the media is writable and not damaged.

The simplest overwrite technique writes the same data everywhere—often just a pattern of all zeros. At a minimum, this will prevent the data from being retrieved simply by reading from the medium again using standard system functions.

To counter more advanced data recovery techniques, specific overwrite patterns are often prescribed. These may be generic patterns intended to eradicate any trace signatures. For example, writing repeated, alternating patterns of ones and zeros may be more effective than zeros alone. Combinations of patterns are frequently specified.

One challenge with an overwrite is that some areas of the disk may be inaccessible, due to media degradation or other errors. Software overwrite may also be problematic in high-security environments which require stronger controls on data commingling than can be provided by the software in use. The use of advanced storage technologies may also make file-based overwrite ineffective.

Feasibility of recovering overwritten data

Peter Gutmann investigated data recovery from nominally overwritten media in the mid-1990s. He suggested magnetic force microscopy may be able to recover such data, and developed specific patterns, for specific drive technologies, designed to counter such.[2] These patterns have come to be known as the Gutmann method.

Daniel Feenberg, an economist at the private National Bureau of Economic Research, claims that the chances of overwritten data being recovered from a modern hard drive amount to "urban legend".[3] He also points to the "18½ minute gap" Rose Mary Woods created on a tape of Richard Nixon discussing the Watergate break-in. Erased information in the gap has not been recovered, and Feenberg claims doing so would be an easy task compared to recovery of a modern high density digital signal.

As of November 2007, the United States Department of Defense considers overwriting acceptable for clearing magnetic media within the same security area/zone, but not as a sanitization method. Only degaussing or physical destruction is acceptable for the latter.[4]

On the other hand, according to the 2006 NIST Special Publication 800-88 (p. 7): "Studies have shown that most of today’s media can be effectively cleared by one overwrite" and "for ATA disk drives manufactured after 2001 (over 15 GB) the terms clearing and purging have converged."[1] An analysis by Wright et al. of recovery techniques, including magnetic force microscopy, also concludes that a single wipe is all that is required for modern drives. They point out that the long time required for multiple wipes "has created a situation where many organisations ignore the issue all together – resulting in data leaks and loss. "[5]

Degaussing

Degaussing is the removal or reduction of a magnetic field of a disk or drive, using a device called a degausser that that has been designed for the media being erased. Applied to magnetic media, degaussing may purge an entire media element quickly and effectively.

Degaussing often renders hard disks inoperable, as it erases low-level formatting that is only done at the factory during manufacturing. Degaussed floppy disks can generally be reformatted and reused, though.

In some high-security environments, one may be required to use a degausser that has been approved for the task. For example, in US government and military jurisdictions, one may be required to use a degausser from the NSA's "Evaluated Products List".[6].

Encryption

Encrypting data before it is stored on the medium may mitigate concerns about data remanence. If the decryption key is strong and carefully controlled (i.e., not itself subject to data remanence), it may effectively make any data on the medium unrecoverable. Even if the key is stored on the medium, it may prove easier or quicker to overwrite just the key, vs the entire disk.

Encryption may be done on a file-by-file basis, or on the whole disk. However if the key is stored, even temporarily, on the same system as the data, it is subject to data remanence and may be recovered by an attacker. See cold boot attack.

Physical destruction

Thorough physical destruction of the entire data storage medium is generally considered the most certain way to counter data remanence. However, the process is generally time-consuming and cumbersome. Physical destruction may require extremely thorough methods, as even a small media fragment may contain large amounts of data.

Specific destruction techniques include:

  • Physically breaking the media apart, by grinding, shredding, etc.
  • Incinerating
  • Phase transition (i.e., liquification or vaporization of a solid disk)
  • Application of corrosive chemicals, such as acids, to recording surfaces
  • For magnetic media, raising its temperature above the Curie point
  • For many electric volatile and non-volatile storage mediums, application of extremely high voltage as compared to safe operational specifications

Complications

Inaccessible media areas

Storage media may have areas which become inaccessible by normal means. For example, magnetic disks may develop new "bad sectors" after data has been written, and tapes require inter-record gaps. Modern hard disks often feature automatic remapping of marginal sectors or tracks, which the OS may not even be aware of. Attempts to counter data remanence by overwriting may not be successful in such situations, as data remnants may persist in such nominally inaccessible areas.

Advanced storage systems

Data storage systems with more sophisticated features may make overwrite ineffective, especially on a per-file basis.

Journaling file systems increase the integrity of data by recording write operations in multiple locations, and applying transaction-like semantics. On such systems, data remnants may exist in locations "outside" the nominal file storage location.

Some file systems implement copy-on-write or built-in revision control, with the intent that writing to a file never overwrites data in-place.

Technologies such as RAID and anti-fragmentation techniques may result in file data being written to multiple locations, either by design (for fault tolerance), or as data remnants.

Wear levelling can also defeat data erasure, by relocating blocks between the time when they are originally written and the time when they are overwritten.

Optical media

Optical media are not magnetic and are not affected by degaussing. Write-once optical media (CD-R, DVD-R, etc.) also cannot be purged by overwrite. Read/write optical media, such as CD-RW and DVD-RW, may be receptive to overwriting. Methods for successfully sanitizing optical discs include delaminating-abrasion of the metallic data layer, shredding, destructive electrical arcing (as by exposure to microwave energy), and submersion in a polycarbonate solvent (e.g., acetone).

Data in RAM

Data remanence has been observed in static RAM, which is typically considered volatile (i.e., contents are erased with loss of electrical power). In the study, data retention was sometimes observed even at room temperature.[7]

Another study found data remanence in dynamic random access memory (DRAM), again with data retention of seconds to minutes at room temperature and "a full week without refresh when cooled with liquid nitrogen."[8] The study authors were able to use a cold boot attack to recover cryptographic keys for several popular full disk encryption systems. Despite some memory degradation, they were able to take advantage of redundancy in the way keys are stored after they have been expanded for efficient use, such as in key scheduling. The authors recommend that computers be powered down, rather than be left in a "sleep" state, when not in physical control of the owner, and in some cases such as one where you have the software program Bitlocker, that a boot PIN also be configured.[8] Modern RAM chips have a built-in self-refresh module so they can retain data for as long as they have power supply and a clock signal.

Standards

  • US NIST Special Publication 800-88: Guidelines for Media Sanitization[1]
  • US DoD 5220.22-M: National Industrial Security Program Operating Manual (NISPOM)
    • Current editions no longer contain any references to specific sanitization methods. Standards for sanitization are left up to the Cognizant Security Authority.[9]
    • Although the NISPOM text itself never described any specific methods for sanitization, past editions (1995 and 1997)[10] did contain explicit sanitization methods within the DSS C&SM table inserted after Section 8-306.
    • The Defense Security Service (DSS) provides a Clearing and Sanitization Matrix (C&SM) which does specify methods[4].
    • As of the Nov 2007 edition of the DSS C&SM, overwriting is no longer acceptable for sanitization of magnetic media. Only degaussing (with an NSA approved degausser) or physical destruction is acceptable.
  • NAVSO P5239-26 [1]
  • AFSSI-5020
  • AR380-19
  • RCMP G2-003: Hard Drive Secure Information Removal and Destruction Guidelines[11]
    • Up to A/B/Confidential data: Triple overwrite using RCMP DSX software (or equivalent)[12]
    • C/Secret/Top Secret data: Physical destruction or degaussing

See also

Software

There are dozens of other tools for various operating systems.

Notes

  1. ^ a b c "Special Publication 800-88: Guidelines for Media Sanitization" (PDF). NIST. September 2006. http://csrc.nist.gov/publications/nistpubs/800-88/NISTSP800-88_rev1.pdf. Retrieved 2007-12-08.   (542 KB)
  2. ^ Peter Gutmann (July 1996). Secure Deletion of Data from Magnetic and Solid-State Memory. http://www.cs.auckland.ac.nz/~pgut001/pubs/secure_del.html. Retrieved 2007-12-10.  
  3. ^ Daniel Feenberg. Can Intelligence Agencies Recover Overwritten Data?. http://www.nber.org/sys-admin/overwritten-data-guttman.html. Retrieved 2007-12-10.  
  4. ^ a b "DSS Clearing & Sanitization Matrix" (PDF). DSS. 2007-11-12. https://www.dss.mil/portal/ShowBinary/BEA%20Repository/new_dss_internet/isp/odaa/documents/clear_n_san_matrix_06282007_rev_11122007.pdf. Retrieved 2007-11-25.   (89 KB)
  5. ^ Wright, Craig; Kleiman, Dave; Sundhar R.S., Shyaam (December 2008). "Overwriting Hard Drive Data: The Great Wiping Controversy". Lecture Notes in Computer Science (Springer Berlin / Heidelberg). doi:10.1007/978-3-540-89862-7_21. ISBN 978-3-540-89861-0.  
  6. ^ "Media Destruction Guidance". NSA. http://www.nsa.gov/ia/guidance/media_destruction_guidance/. Retrieved 2009-03-01.  
  7. ^ Sergei Skorobogatov (June 2002). Low temperature data remanence in static RAM. University of Cambridge, Computer Laboratory. http://www.cl.cam.ac.uk/techreports/UCAM-CL-TR-536.html.  
  8. ^ a b J. Alex Halderman, et al. (February 2008) (PDF). Lest We Remember: Cold Boot Attacks on Encryption Keys. http://citp.princeton.edu.nyud.net/pub/coldboot.pdf.  
  9. ^ "Download NISPOM". DSS. https://www.dss.mil/portal/ShowBinary/BEA%20Repository/new_dss_internet/isp/fac_clear/download_nispom.html. Retrieved 2007-11-25.  
  10. ^ "Obsolete NISPOM" (PDF). January 1995. http://www.usaid.gov/policy/ads/500/d522022m.pdf. Retrieved 2007-12-07.   with the DSS Clearing and Sanitization Matrix; includes Change 1, July 31, 1997.
  11. ^ "Hard Drive Secure Information Removal and Destruction Guidelines" (PDF). Royal Canadian Mounted Police. October 2003. http://www.rcmp-grc.gc.ca/ts-st/pubs/it-ti-sec/g2-003-eng.pdf.  
  12. ^ "Suggested DSX Replacement Products" (PDF). Royal Canadian Mounted Police. October 2007. http://www.rcmp-grc.gc.ca/ts-st/pubs/it-ti-sec/b2-001-eng.pdf.  

References








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