How does proof of stake (PoS) differ from PoW?
How Does Proof of Stake (PoS) Differ from Proof of Work (PoW)?
Understanding the core differences between Proof of Stake (PoS) and Proof of Work (PoW) is essential for anyone interested in blockchain technology, cryptocurrencies, or the future of decentralized finance. Both mechanisms serve as consensus algorithms—methods that ensure all participants agree on the state of a blockchain—but they operate on fundamentally different principles. This article explores these differences, their historical development, recent trends, and potential implications for the industry.
The Origins and Development of PoW and PoS
Proof of Work was introduced with Bitcoin in 2008 by Satoshi Nakamoto. It was designed to create a secure, decentralized digital currency without relying on central authorities. Miners compete to solve complex mathematical puzzles using computational power; the first to succeed adds a new block to the blockchain and earns rewards in cryptocurrency tokens like Bitcoin.
In contrast, Proof of Stake emerged later as an energy-efficient alternative. Proposed by Sunny King and Scott Nadal in 2012 under the name "Ouroboros," PoS assigns validation rights based on how much cryptocurrency a user holds—referred to as their "stake." Instead of solving puzzles with hardware-intensive computations, validators are chosen probabilistically based on their stake size.
This shift from energy-heavy mining to stake-based validation reflects broader concerns about sustainability within blockchain networks while aiming for faster transaction processing times.
How Do PoW and PoS Operate?
Proof of Work involves miners competing simultaneously; they use powerful hardware like ASICs or GPUs to perform trillions of calculations per second until one finds a valid solution. This process requires significant electricity consumption because it relies heavily on computational effort. Once solved, this puzzle confirms that miners have expended resources—making malicious attacks costly due to high energy costs.
Proof of Stake, however, selects validators proportionally based on their holdings rather than computational work. When creating new blocks or validating transactions, stakeholders lock up some amount of cryptocurrency as collateral—a process called "staking." Validators are then randomly selected or weighted according to their stake size; those with larger stakes have higher chances but cannot always dominate due to randomization mechanisms designed for decentralization.
This approach reduces energy consumption dramatically since it eliminates intensive calculations altogether while maintaining network security through economic incentives: misbehavior can lead validators losing their staked assets ("slashing").
Key Advantages and Disadvantages
Security Considerations
PoW is widely regarded as highly secure because attacking such networks requires enormous computing power—making attacks economically unfeasible for most adversaries. However, this security comes at high operational costs due to electricity usage.
PoS offers comparable security if well-designed but faces criticism over potential centralization risks: wealthy stakeholders could exert disproportionate influence over network decisions unless safeguards are implemented through protocols like randomized validator selection or delegated voting systems.
Energy Efficiency
One major differentiator is energy consumption:
- PoW: Known for its substantial environmental footprint; Bitcoin alone consumes around 73 TWh annually—a level comparable with small countries.
- PoS: Significantly more eco-friendly since it does not require extensive hardware operations; Ethereum’s transition from PoW has been driven largely by sustainability concerns.
Scalability Potential
Scalability remains an ongoing challenge:
- PoW networks often face limitations due to block creation times and resource constraints.
- PoS systems tend toward higher throughput capabilities because they do not rely on resource-intensive computations—and many projects aim specifically at improving scalability via layer-two solutions built atop PoS chains like Ethereum 2.0's sharding mechanism.
Market Adoption Examples
Bitcoin exemplifies pure PoW consensus—its security model has made it resilient against attacks over years despite criticisms about environmental impact. Ethereum’s shift post-2022 ("The Merge") marks one notable adoption case where transitioning from PoW improved efficiency without compromising decentralization significantly.
Other prominent projects such as Cardano and Tezos utilize pure or hybrid proof-of-stake models emphasizing sustainability alongside robust governance features.
Recent Trends: The Shift Toward Energy-Efficient Blockchains
The move by Ethereum—from its original proof-of-work system—to a full proof-of-stake protocol represents one of the most significant developments in recent years within crypto infrastructure development. Launched successfully in September 2022 ("The Merge"), this transition aimed primarily at reducing carbon footprints while enhancing scalability prospects—a key concern among regulators worldwide increasingly scrutinizing crypto's environmental impact.
Additionally, central banks exploring digital currencies are considering staking-based models when designing Central Bank Digital Currencies (CBDCs). For example, research conducted by institutions like the Bank of England indicates interest in leveraging proof-of-stake concepts for efficient monetary systems that balance security with low operational costs.
Challenges Facing Proof-of-Stake Systems
Despite its advantages—including lower energy use—the implementation details pose challenges:
Centralization Risks: Large stakeholders may gain disproportionate influence unless protocols incorporate measures such as random validator selection.
Security Concerns: While theoretically secure under certain assumptions (e.g., honest majority), some critics argue that large token holders could manipulate outcomes if controls aren’t properly enforced.
Regulatory Uncertainty: As governments develop frameworks around cryptocurrencies’ legal status—including staking rewards—the regulatory landscape remains uncertain which could impact future adoption rates.
Furthermore, market dynamics can be affected during transitions between consensus mechanisms—for instance when Ethereum shifted from PoW—which often leads investors' optimism but also introduces technical complexities during upgrades.
Impact on Cryptocurrency Markets & Ecosystem Development
The transition toward proof-of-stake influences investor confidence positively when perceived benefits include reduced environmental impact coupled with enhanced scalability prospects—all critical factors influencing mainstream adoption efforts.
Moreover, staking allows users not only participate actively but also earn passive income through staking rewards—a feature attracting retail investors seeking yield opportunities beyond traditional markets.
However—as seen during Ethereum’s upgrade—the market can experience volatility amid technological shifts or regulatory announcements affecting sentiment across various tokens utilizing either consensus method.
By understanding these fundamental differences between Proof-of-Stake and Proof-of-Work—and recognizing ongoing trends—they become clearer why many projects are gravitating toward more sustainable models without sacrificing security standards essential for decentralized trustworthiness.
As blockchain technology continues evolving rapidly—with innovations aimed at balancing decentralization , scalability ,and sustainability—it’s crucial both developers and users stay informed about these foundational mechanisms shaping our digital financial future.
References
- Nakamoto S., “Bitcoin: A Peer-to-Peer Electronic Cash System,” 2008.
- King S., Nadal S., “Ouroboros: A Provably Secure Proof-of-Stake Blockchain Protocol,” 2012.
- Ethereum Foundation,“The Merge: Ethereum's Transition to Proof Of Stake,” 2022.4.“Central Bank Digital Currencies: A Review,” Bank Of England ,2023
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2025-05-14 05:51
How does proof of stake (PoS) differ from PoW?
How Does Proof of Stake (PoS) Differ from Proof of Work (PoW)?
Understanding the core differences between Proof of Stake (PoS) and Proof of Work (PoW) is essential for anyone interested in blockchain technology, cryptocurrencies, or the future of decentralized finance. Both mechanisms serve as consensus algorithms—methods that ensure all participants agree on the state of a blockchain—but they operate on fundamentally different principles. This article explores these differences, their historical development, recent trends, and potential implications for the industry.
The Origins and Development of PoW and PoS
Proof of Work was introduced with Bitcoin in 2008 by Satoshi Nakamoto. It was designed to create a secure, decentralized digital currency without relying on central authorities. Miners compete to solve complex mathematical puzzles using computational power; the first to succeed adds a new block to the blockchain and earns rewards in cryptocurrency tokens like Bitcoin.
In contrast, Proof of Stake emerged later as an energy-efficient alternative. Proposed by Sunny King and Scott Nadal in 2012 under the name "Ouroboros," PoS assigns validation rights based on how much cryptocurrency a user holds—referred to as their "stake." Instead of solving puzzles with hardware-intensive computations, validators are chosen probabilistically based on their stake size.
This shift from energy-heavy mining to stake-based validation reflects broader concerns about sustainability within blockchain networks while aiming for faster transaction processing times.
How Do PoW and PoS Operate?
Proof of Work involves miners competing simultaneously; they use powerful hardware like ASICs or GPUs to perform trillions of calculations per second until one finds a valid solution. This process requires significant electricity consumption because it relies heavily on computational effort. Once solved, this puzzle confirms that miners have expended resources—making malicious attacks costly due to high energy costs.
Proof of Stake, however, selects validators proportionally based on their holdings rather than computational work. When creating new blocks or validating transactions, stakeholders lock up some amount of cryptocurrency as collateral—a process called "staking." Validators are then randomly selected or weighted according to their stake size; those with larger stakes have higher chances but cannot always dominate due to randomization mechanisms designed for decentralization.
This approach reduces energy consumption dramatically since it eliminates intensive calculations altogether while maintaining network security through economic incentives: misbehavior can lead validators losing their staked assets ("slashing").
Key Advantages and Disadvantages
Security Considerations
PoW is widely regarded as highly secure because attacking such networks requires enormous computing power—making attacks economically unfeasible for most adversaries. However, this security comes at high operational costs due to electricity usage.
PoS offers comparable security if well-designed but faces criticism over potential centralization risks: wealthy stakeholders could exert disproportionate influence over network decisions unless safeguards are implemented through protocols like randomized validator selection or delegated voting systems.
Energy Efficiency
One major differentiator is energy consumption:
- PoW: Known for its substantial environmental footprint; Bitcoin alone consumes around 73 TWh annually—a level comparable with small countries.
- PoS: Significantly more eco-friendly since it does not require extensive hardware operations; Ethereum’s transition from PoW has been driven largely by sustainability concerns.
Scalability Potential
Scalability remains an ongoing challenge:
- PoW networks often face limitations due to block creation times and resource constraints.
- PoS systems tend toward higher throughput capabilities because they do not rely on resource-intensive computations—and many projects aim specifically at improving scalability via layer-two solutions built atop PoS chains like Ethereum 2.0's sharding mechanism.
Market Adoption Examples
Bitcoin exemplifies pure PoW consensus—its security model has made it resilient against attacks over years despite criticisms about environmental impact. Ethereum’s shift post-2022 ("The Merge") marks one notable adoption case where transitioning from PoW improved efficiency without compromising decentralization significantly.
Other prominent projects such as Cardano and Tezos utilize pure or hybrid proof-of-stake models emphasizing sustainability alongside robust governance features.
Recent Trends: The Shift Toward Energy-Efficient Blockchains
The move by Ethereum—from its original proof-of-work system—to a full proof-of-stake protocol represents one of the most significant developments in recent years within crypto infrastructure development. Launched successfully in September 2022 ("The Merge"), this transition aimed primarily at reducing carbon footprints while enhancing scalability prospects—a key concern among regulators worldwide increasingly scrutinizing crypto's environmental impact.
Additionally, central banks exploring digital currencies are considering staking-based models when designing Central Bank Digital Currencies (CBDCs). For example, research conducted by institutions like the Bank of England indicates interest in leveraging proof-of-stake concepts for efficient monetary systems that balance security with low operational costs.
Challenges Facing Proof-of-Stake Systems
Despite its advantages—including lower energy use—the implementation details pose challenges:
Centralization Risks: Large stakeholders may gain disproportionate influence unless protocols incorporate measures such as random validator selection.
Security Concerns: While theoretically secure under certain assumptions (e.g., honest majority), some critics argue that large token holders could manipulate outcomes if controls aren’t properly enforced.
Regulatory Uncertainty: As governments develop frameworks around cryptocurrencies’ legal status—including staking rewards—the regulatory landscape remains uncertain which could impact future adoption rates.
Furthermore, market dynamics can be affected during transitions between consensus mechanisms—for instance when Ethereum shifted from PoW—which often leads investors' optimism but also introduces technical complexities during upgrades.
Impact on Cryptocurrency Markets & Ecosystem Development
The transition toward proof-of-stake influences investor confidence positively when perceived benefits include reduced environmental impact coupled with enhanced scalability prospects—all critical factors influencing mainstream adoption efforts.
Moreover, staking allows users not only participate actively but also earn passive income through staking rewards—a feature attracting retail investors seeking yield opportunities beyond traditional markets.
However—as seen during Ethereum’s upgrade—the market can experience volatility amid technological shifts or regulatory announcements affecting sentiment across various tokens utilizing either consensus method.
By understanding these fundamental differences between Proof-of-Stake and Proof-of-Work—and recognizing ongoing trends—they become clearer why many projects are gravitating toward more sustainable models without sacrificing security standards essential for decentralized trustworthiness.
As blockchain technology continues evolving rapidly—with innovations aimed at balancing decentralization , scalability ,and sustainability—it’s crucial both developers and users stay informed about these foundational mechanisms shaping our digital financial future.
References
- Nakamoto S., “Bitcoin: A Peer-to-Peer Electronic Cash System,” 2008.
- King S., Nadal S., “Ouroboros: A Provably Secure Proof-of-Stake Blockchain Protocol,” 2012.
- Ethereum Foundation,“The Merge: Ethereum's Transition to Proof Of Stake,” 2022.4.“Central Bank Digital Currencies: A Review,” Bank Of England ,2023
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How Does Proof of Stake (PoS) Differ from Proof of Work (PoW)?
Understanding the core differences between Proof of Stake (PoS) and Proof of Work (PoW) is essential for anyone interested in blockchain technology, cryptocurrencies, or the future of decentralized finance. Both mechanisms serve as consensus algorithms—methods that ensure all participants agree on the state of a blockchain—but they operate on fundamentally different principles. This article explores these differences, their historical development, recent trends, and potential implications for the industry.
The Origins and Development of PoW and PoS
Proof of Work was introduced with Bitcoin in 2008 by Satoshi Nakamoto. It was designed to create a secure, decentralized digital currency without relying on central authorities. Miners compete to solve complex mathematical puzzles using computational power; the first to succeed adds a new block to the blockchain and earns rewards in cryptocurrency tokens like Bitcoin.
In contrast, Proof of Stake emerged later as an energy-efficient alternative. Proposed by Sunny King and Scott Nadal in 2012 under the name "Ouroboros," PoS assigns validation rights based on how much cryptocurrency a user holds—referred to as their "stake." Instead of solving puzzles with hardware-intensive computations, validators are chosen probabilistically based on their stake size.
This shift from energy-heavy mining to stake-based validation reflects broader concerns about sustainability within blockchain networks while aiming for faster transaction processing times.
How Do PoW and PoS Operate?
Proof of Work involves miners competing simultaneously; they use powerful hardware like ASICs or GPUs to perform trillions of calculations per second until one finds a valid solution. This process requires significant electricity consumption because it relies heavily on computational effort. Once solved, this puzzle confirms that miners have expended resources—making malicious attacks costly due to high energy costs.
Proof of Stake, however, selects validators proportionally based on their holdings rather than computational work. When creating new blocks or validating transactions, stakeholders lock up some amount of cryptocurrency as collateral—a process called "staking." Validators are then randomly selected or weighted according to their stake size; those with larger stakes have higher chances but cannot always dominate due to randomization mechanisms designed for decentralization.
This approach reduces energy consumption dramatically since it eliminates intensive calculations altogether while maintaining network security through economic incentives: misbehavior can lead validators losing their staked assets ("slashing").
Key Advantages and Disadvantages
Security Considerations
PoW is widely regarded as highly secure because attacking such networks requires enormous computing power—making attacks economically unfeasible for most adversaries. However, this security comes at high operational costs due to electricity usage.
PoS offers comparable security if well-designed but faces criticism over potential centralization risks: wealthy stakeholders could exert disproportionate influence over network decisions unless safeguards are implemented through protocols like randomized validator selection or delegated voting systems.
Energy Efficiency
One major differentiator is energy consumption:
- PoW: Known for its substantial environmental footprint; Bitcoin alone consumes around 73 TWh annually—a level comparable with small countries.
- PoS: Significantly more eco-friendly since it does not require extensive hardware operations; Ethereum’s transition from PoW has been driven largely by sustainability concerns.
Scalability Potential
Scalability remains an ongoing challenge:
- PoW networks often face limitations due to block creation times and resource constraints.
- PoS systems tend toward higher throughput capabilities because they do not rely on resource-intensive computations—and many projects aim specifically at improving scalability via layer-two solutions built atop PoS chains like Ethereum 2.0's sharding mechanism.
Market Adoption Examples
Bitcoin exemplifies pure PoW consensus—its security model has made it resilient against attacks over years despite criticisms about environmental impact. Ethereum’s shift post-2022 ("The Merge") marks one notable adoption case where transitioning from PoW improved efficiency without compromising decentralization significantly.
Other prominent projects such as Cardano and Tezos utilize pure or hybrid proof-of-stake models emphasizing sustainability alongside robust governance features.
Recent Trends: The Shift Toward Energy-Efficient Blockchains
The move by Ethereum—from its original proof-of-work system—to a full proof-of-stake protocol represents one of the most significant developments in recent years within crypto infrastructure development. Launched successfully in September 2022 ("The Merge"), this transition aimed primarily at reducing carbon footprints while enhancing scalability prospects—a key concern among regulators worldwide increasingly scrutinizing crypto's environmental impact.
Additionally, central banks exploring digital currencies are considering staking-based models when designing Central Bank Digital Currencies (CBDCs). For example, research conducted by institutions like the Bank of England indicates interest in leveraging proof-of-stake concepts for efficient monetary systems that balance security with low operational costs.
Challenges Facing Proof-of-Stake Systems
Despite its advantages—including lower energy use—the implementation details pose challenges:
Centralization Risks: Large stakeholders may gain disproportionate influence unless protocols incorporate measures such as random validator selection.
Security Concerns: While theoretically secure under certain assumptions (e.g., honest majority), some critics argue that large token holders could manipulate outcomes if controls aren’t properly enforced.
Regulatory Uncertainty: As governments develop frameworks around cryptocurrencies’ legal status—including staking rewards—the regulatory landscape remains uncertain which could impact future adoption rates.
Furthermore, market dynamics can be affected during transitions between consensus mechanisms—for instance when Ethereum shifted from PoW—which often leads investors' optimism but also introduces technical complexities during upgrades.
Impact on Cryptocurrency Markets & Ecosystem Development
The transition toward proof-of-stake influences investor confidence positively when perceived benefits include reduced environmental impact coupled with enhanced scalability prospects—all critical factors influencing mainstream adoption efforts.
Moreover, staking allows users not only participate actively but also earn passive income through staking rewards—a feature attracting retail investors seeking yield opportunities beyond traditional markets.
However—as seen during Ethereum’s upgrade—the market can experience volatility amid technological shifts or regulatory announcements affecting sentiment across various tokens utilizing either consensus method.
By understanding these fundamental differences between Proof-of-Stake and Proof-of-Work—and recognizing ongoing trends—they become clearer why many projects are gravitating toward more sustainable models without sacrificing security standards essential for decentralized trustworthiness.
As blockchain technology continues evolving rapidly—with innovations aimed at balancing decentralization , scalability ,and sustainability—it’s crucial both developers and users stay informed about these foundational mechanisms shaping our digital financial future.
References
- Nakamoto S., “Bitcoin: A Peer-to-Peer Electronic Cash System,” 2008.
- King S., Nadal S., “Ouroboros: A Provably Secure Proof-of-Stake Blockchain Protocol,” 2012.
- Ethereum Foundation,“The Merge: Ethereum's Transition to Proof Of Stake,” 2022.4.“Central Bank Digital Currencies: A Review,” Bank Of England ,2023
How Does Proof of Stake (PoS) Differ from Proof of Work (PoW)?
Understanding the core differences between Proof of Stake (PoS) and Proof of Work (PoW) is essential for anyone interested in blockchain technology, cryptocurrencies, or decentralized networks. Both mechanisms serve as consensus algorithms that validate transactions and secure the network, but they operate on fundamentally different principles. This article provides a comprehensive comparison to help you grasp how each system functions, their advantages and disadvantages, and recent developments shaping their future.
What Is Proof of Work (PoW)?
Proof of Work is the original consensus mechanism introduced by Bitcoin in 2009. It relies on miners competing to solve complex mathematical puzzles using computational power. The first miner to find a valid solution earns the right to add a new block to the blockchain and receives cryptocurrency rewards in return.
This process demands significant energy because solving these puzzles requires specialized hardware performing trillions of calculations per second. The security model hinges on this high energy cost; attacking a PoW network would require an attacker to control more than 50% of its computational power—a feat that becomes prohibitively expensive at scale.
Bitcoin remains the most prominent example utilizing PoW, demonstrating its robustness but also highlighting its environmental impact due to substantial electricity consumption. Ethereum's initial implementation also used PoW before transitioning to PoS in 2022.
However, PoW faces notable challenges: high operational costs driven by energy use and limited scalability due to resource-intensive mining processes. These issues have led many developers and communities seeking greener alternatives or more scalable solutions.
What Is Proof of Stake (PoS)?
Proof of Stake offers an alternative approach where validators are chosen based on how much cryptocurrency they hold—referred to as their "stake." Instead of solving mathematical puzzles, validators are selected probabilistically relative to their stake size; larger stakes increase chances for validation rights.
This method significantly reduces energy consumption because it eliminates intensive computations altogether. Security relies on economic incentives: validators have a financial interest in acting honestly since malicious behavior could lead them losing their staked assets—a concept known as "slashing."
Ethereum's transition from PoW was motivated partly by these benefits—aiming for increased scalability while reducing environmental impact. Other prominent projects like Cardano with Ouroboros protocol or Tezos employ variants of PoS designed for security and decentralization balance.
Advantages include lower operational costs, higher transaction throughput potential, and better suitability for scaling solutions such as sharding or layer-2 protocols. Nonetheless, concerns about centralization persist if large stakeholders dominate validation processes—potentially undermining decentralization goals intrinsic to blockchain technology.
Recent Developments Shaping Consensus Mechanisms
The shift from PoW toward PoS has been one of the most significant trends recently observed within blockchain ecosystems:
Ethereum’s Transition: Completed successfully in September 2022 with Ethereum’s “Merge,” this move marked a pivotal moment emphasizing sustainability alongside scalability.
Innovations in Variants: Projects like Cardano utilize Ouroboros—a proof-of-stake algorithm designed explicitly for security efficiency—and Tezos employs liquid proof-of-stake models balancing decentralization with performance.
Debates & Industry Impact: While many see PoS as vital for sustainable growth amid rising environmental concerns, critics argue it might lead toward centralization if large stakeholders gain disproportionate influence over network validation processes.
Regulatory Considerations: Governments worldwide are increasingly scrutinizing consensus mechanisms; some jurisdictions favor energy-efficient options like PoS when drafting regulations related to cryptocurrencies’ environmental footprint.
These developments reflect ongoing efforts within blockchain communities aiming at optimizing security models while addressing ecological impacts—a critical factor influencing mainstream adoption strategies.
Key Factors Comparing Proof-of-Stake vs Proof-of-Work
| Aspect | Proof-of-Work | Proof-of-Stake |
|---|---|---|
| Energy Consumption | High | Low |
| Hardware Requirements | Specialized mining rigs | Standard hardware or minimal requirements |
| Security Model | Computational difficulty & cost | Economic incentives & penalties |
| Scalability Potential | Limited without layer-two solutions | Higher potential through various scaling methods |
| Centralization Risks | Mining pools can dominate | Large stakeholders may exert influence |
Understanding these factors helps users evaluate which mechanism aligns best with specific project goals—whether prioritizing security robustness or sustainability considerations.
How Blockchain Projects Choose Between PoW and PoS
The decision often depends on multiple factors including desired scalability levels, environmental commitments, community preferences, regulatory landscape—and even technological maturity:
Security Needs: For highly secure networks requiring proven resilience against attacks—like Bitcoin—PoW remains dominant.
Environmental Goals: Projects aiming for eco-friendliness tend toward adopting or developing efficient variants like PoS.
Scalability Requirements: For applications demanding rapid transaction processing at scale—for instance decentralized finance platforms—PoS offers promising avenues.
Community & Developer Support: Established ecosystems may prefer proven mechanisms; newer projects might experiment with hybrid approaches combining elements from both systems.
Future Outlook
As blockchain technology matures amidst increasing scrutiny over ecological impacts and regulatory pressures worldwide:
More projects will likely adopt energy-efficient consensus algorithms such as variants of proof-of-stake.
Innovations aimed at mitigating centralization risks associated with large stakes will be crucial—for example through delegated staking models or randomized validator selection methods.
Hybrid models combining aspects from both mechanisms could emerge further enhancing security while maintaining sustainability goals.
Final Thoughts
Choosing between proof-of-work versus proof-of-stake involves weighing trade-offs related primarily to energy efficiency versus proven security frameworks rooted in computational work difficulty versus economic incentives respectively. Recent shifts exemplified by Ethereum’s transition highlight industry momentum towards greener alternatives aligned with broader societal priorities around climate change mitigation without compromising decentralization principles too heavily.
Staying informed about ongoing technological advancements ensures participants—from developers designing new protocols—to investors assessing long-term viability can make educated decisions aligned with evolving standards within this dynamic field.