Incomputing,overclocking is the practice of increasing theclock rate of asemiconductor device, such as aprocessor, beyond its rated speed, potentially increasing itsperformance.[1] Overclocked devices, however, may have shorter lifespans, become unstable and unreliable, and in extreme cases, be permanently damaged. Many manufacturers do not cover damage from overclocking in theirwarranties, while some allow it inside a predefined safety margin.
A semiconductor device's processing speed depends on a variety of factors, including, but not limited to, its clock speed,microarchitecture, the kind ofsoftware it's running, and thebandwidth,latency and size foreach level of itsmemory. All else being equal, a faster-clocked device can, though not necessarily, perform faster. Operatingvoltage is often increased to maintain a component's operational stability at accelerated speeds. Operating at higher frequencies and voltages increase power consumption and heat.[2] Overclocking a device introduces additional risks of failure, for example, by overheating when the increased heat load is not removed,[2] or by the device requesting more power than its power supply can provide.[citation needed]
Underclocking ordownclocking is the practice of lowering a device's clock rate to below its default. An underclocked device trades lowered performance for reductions in power consumption and heat output. Such a device can potentially be cooled with less capable heatsinks, or, if present at all, slower rotating fans forquieter operation. For devices powered by abattery, e.g.,smartphones andlaptops, underclocking can be used to lower power consumption and extendbattery life; some devices underclock themselves automatically when operating under battery power.[3]
Underclocking and undervolting would be attempted on a desktop system to have it operate silently (such as for a home entertainment center) while potentially offering higher performance than currently offered by low-voltage processor offerings. This would use a "standard-voltage" part and attempt to run with lower voltages (while attempting to keep the desktop speeds) to meet an acceptable performance/noise target for the build. This was also attractive as using a "standard voltage" processor in a "low voltage" application avoided paying the traditional price premium for an officially certified lowvoltage version. However again like overclocking there is no guarantee of success, and the builder's time researching given system/processor combinations and especially the time and tedium of performing many iterations of stability testing need to be considered. The usefulness of underclocking (again like overclocking) is determined by what processor offerings, prices, and availability are at the specific time of the build. Underclocking is also sometimes used whentroubleshooting.[4]
Overclocking has become more accessible with motherboard makers offering overclocking as a marketing feature on their mainstream product lines. However, the practice is embraced more byenthusiasts than professional users, as overclocking carries a risk of reduced reliability, accuracy and damage to data and equipment. Additionally, most manufacturer warranties and service agreements do not cover overclocked components nor any incidental damages caused by their use. While overclocking can still be an option for increasing personal computing capacity, and thus workflow productivity for professional users, the importance of stability testing components thoroughlybefore employing them into a production environment cannot be overstated.
Overclocking offers several draws for overclocking enthusiasts. Overclocking allows testing of components at speeds not currently offered by the manufacturer, or at speeds only officially offered on specialized, higher-priced versions of the product. A general trend in the computing industry is that new technologies tend to debut in the high-end market first, then later trickle down to the performance and mainstream market. If the high-end part only differs by an increased clock speed, an enthusiast can attempt to overclock a mainstream part to simulate the high-end offering. This can give insight on how over-the-horizon technologies will perform before they are officially available on the mainstream market, which can be especially helpful for other users considering if they should plan ahead to purchase or upgrade to the new feature when it is officially released.
Some hobbyists enjoy building, tuning, and "Hot-Rodding" their systems in competitive benchmarking competitions, competing with other like-minded users for high scores in standardized computer benchmark suites. Others will purchase a low-cost model of a component in a given product line, and attempt to overclock that part to match a more expensive model's stock performance. Another approach is overclocking older components to attempt to keep pace with increasingsystem requirements and extend the useful service life of the older part or at least delay purchase of new hardware solely for performance reasons. Another rationale for overclocking older equipment is even if overclocking stresses equipment to the point of failure earlier, little is lost as it is alreadydepreciated, and would have needed to be replaced in any case.[5]
While stock cooling systems are commonly designed for heat produced during non-overclocked use, they may not be adequate for overclocked parts. These may include the use of additional and more powerfulfans, larger and more efficientheat sinks,heat pipes, or the use ofwater cooling.
Heat sinks are passiveheat exchangers designed to take away excessive heat generated by the device it is in physical contact with. They are commonly made withcopper oraluminum, with copper having higherthermal conductivity, and aluminum being less efficient but also cheaper.[6]Heat pipes can be used to improve conductivity. Many heatsinks combine two or more materials to achieve a balance between performance and cost.[6]
Other cooling methods areforced convection andphase transition cooling which is used inrefrigerators and can be adapted for computer use.Liquid nitrogen,liquid helium, anddry ice are used as coolants in extreme cases,[7] such as record-setting attempts or one-off experiments rather than cooling an everyday system. In June 2006,IBM andGeorgia Institute of Technology jointly announced a new record in silicon-based chipclock rate (the rate a transistor can be switched at, not the CPU clock rate[8]) above 500 GHz, which was done by cooling the chip to 4.5 K (−268.6 °C; −451.6 °F) using liquid helium.[9] The current CPU frequency world record is 9,130.33 MHz, achieved in August 2025 with an IntelCore i9-14900KF.[10] These extreme methods are generally impractical in the long term, as they require refilling reservoirs of vaporizing coolant, andcondensation can form on chilled components.[7] Moreover,silicon-basedjunction gate field-effect transistors (JFET) will degrade below temperatures of roughly 100 K (−173 °C; −280 °F) and eventually cease to function or "freeze out" at 40 K (−233 °C; −388 °F) since the silicon ceases to be semiconducting,[11] so using extremely cold coolants may cause devices to fail.Blowtorch is used to temporarily raise temperature to issues of over-cooling when not desirable.[12][13]
Submersion cooling, used by theCray-2supercomputer, involves sinking a part of computer system directly into a chilled liquid that is thermally conductive but has lowelectrical conductivity. The advantage of this technique is that no condensation can form on components.[14] A good submersion liquid isFluorinert made by3M, which is expensive. Another option ismineral oil, but impurities such as those in water might cause it to conduct electricity and damage components viashort circuits.[14]
Amateur overclocking enthusiasts have used a mixture ofdry ice and a solvent with a low freezing point, such asacetone orisopropyl alcohol.[15] Thiscooling bath, often used in laboratories, achieves a temperature of −78 °C (−108 °F).[16]
As an overclocked component operates outside of the manufacturer's recommended operating conditions, it may function incorrectly, leading to system instability. Another risk issilent data corruption by undetected errors. Such failures might never be correctly diagnosed and may instead be incorrectly attributed to software bugs in applications,device drivers, or the operating system. Overclocked use may permanently damage components enough to cause them to misbehave (even under normal operating conditions) without becoming totally unusable.
A large-scale 2011 field study of hardware faults causing a system crash for consumer PCs and laptops showed a four to 20 times increase (depending on CPU manufacturer) in system crashes due to CPU failure for overclocked computers over an eight-month period.[17]
In general, overclockers claim that testing can ensure that an overclocked system is stable and functioning correctly. Although software tools are available for testing hardware stability, it is generally impossible for any private individual to thoroughly test the functionality of a processor.[18]
Some semiconductor manufacturing techniques, like thesilicon on insulator (SOI), produce devices withhysteresis behavior. These circuit's performance is affected by the events of the past, so without carefully targeted tests it is possible for a particular sequence of state changes to work at overclocked rates in one situation but not another even if the voltage and temperature are the same. Such a system may pass stress tests yet experiences instabilities in other programs.[19]
Overclockability arises in part due to the economics of the manufacturing processes of CPUs and other components. In many cases components are manufactured by the same process, and tested after manufacture to determine their actual maximum ratings. Components are then marked with a rating chosen by the market needs of the semiconductor manufacturer. Ifmanufacturing yield is high, more higher-rated components than required may be produced, and the manufacturer may mark and sell higher-performing components as lower-rated for marketing reasons. In some cases, the true maximum rating of the component may exceed even the highest rated component sold. Many devices sold with a lower rating may behave in all ways as higher-rated ones, while in the worst case operation at the higher rating may be more problematical.
Notably, higher clocks must always mean greater waste heat generation, as semiconductors set to high must dump to ground more often. In some cases, this means that the chief drawback of the overclocked part is far more heat dissipated than the maximums published by the manufacturer. Pentium architectBob Colwell calls overclocking an "uncontrolled experiment in better-than-worst-case system operation".[20]
Overclocking is sometimes offered as a legitimate service or feature for consumers, in which a manufacturer or retailer tests the overclocking capability of processors, memory, video cards, and other hardware products. Several video card manufactures now offer factory-overclocked versions of their graphics accelerators, complete with a warranty, usually at a price intermediate between that of the standard product and a non-overclocked product of higher performance.
It is speculated that manufacturers implement overclocking prevention mechanisms such asCPU multiplier locking to prevent users from buying lower-priced items and overclocking them. These measures are sometimes marketed as aconsumer protection benefit, but are often criticized by buyers.
Many motherboards are sold, and advertised, with extensive facilities for overclocking implemented in hardware and controlled byBIOS settings.[21]
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Fans running at higher speeds generate additionalnoise. The increased heat output from a overclocked device might require faster-spinning fans to be adequately cooled. Depending on the speed, model and numbers of fans used, these noise can reach 50 dB or higher, causingannoyance or evenmental distress. Fan noise has been found to be roughly proportional to thefifth power of fan speed, and halving speed reduces noise by about 15 dB.[22]
An overclocked computer may suffer from instability and behave erratically. This can include inconsistent performance (throttling), abrupt shutdown and reboots due tooverheat,overvoltage orovercurrent,data loss anddata corruption.
Increasing the operation frequency of a component will usually increase its thermal output in a linear fashion, while an increase in voltage usually causes thermal power to increase quadratically.[23]
Graphics processing units (GPUs), like allsemiconductor devices, can also have overclocking headroom and the ability to be overclocked. Some graphics card are factory overclocked - the GPU, framebuffer, and both may run at faster speeds than their standard counterparts (e.g.,reference designs), without any configuration.
VF-overclocking [increases] power consumption [as it] is proportional to the clock frequency and the supply voltage squared. [Excessive] switching in transistors from [such overclocking also increases] the temperature of microprocessors [incurring] reliability loss.
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