The Merkle Mountain Belt
November 17, 2025 Β· Declared Dead Β· π arXiv.org
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Authors
Alfonso Cevallos, Robert Hambrock, Alistair Stewart
arXiv ID
2511.13582
Category
cs.DS: Data Structures & Algorithms
Citations
0
Venue
arXiv.org
Last Checked
4 months ago
Abstract
Merkle structures are widely used as commitment schemes: they allow a prover to publish a compact commitment to an ordered list $X$ of items, and then efficiently prove to a verifier that $x_i\in X$ is the $i$-th item in it. We compare different Merkle structures and their corresponding properties as commitment schemes in the context of blockchain applications. Our primary goal is to speed up light client protocols so that, e.g., a user can verify a transaction efficiently from their smartphone. For instance, the Merkle Mountain Range (MMR) yields a succinct scheme: a light client synchronizing for the first time can do so with a complexity sublinear in $|X|$. On the other hand, the Merkle chain, traditionally used to commit to block headers, is not succinct, but it is incremental - a light client resynchronizing frequently can do so with constant complexity - and optimally additive - the structure can be updated in constant time when a new item is appended to list $X$. We introduce new Merkle structures, most notably the Merkle Mountain Belt (MMB), the first to be simultaneously succinct, incremental and optimally additive. A variant called UMMB is also asynchronous: a light client may continue to interact with the network even when out of sync with the public commitment. Our Merkle structures are slightly unbalanced, so that items recently appended to $X$ receive shorter membership proofs than older items. This feature reduces a light client's expected costs, in applications where queries are biased towards recently generated data.
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