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Line 1: {{User:SDZeroBot/NPP sorting/header\|count=2425\|date=730 August 2025\|ts=13:4948, 730 August 2025 (UTC)}} {\| class="wikitable sortable" Line 9: ! scope="col" style="width: 10em;" \| Creator (# edits) ! scope="col" style="width: 4em;" \| Notes \|- ~~\| 2024-12-28~~ ~~\| [[Yang–Baxter operator]] <small>(A mathematical operator used in theoretical physics and topology)</small>~~ \| Yang–Baxter operators are [[invertible]] [[linear operator\|linear]] [[endomorphisms]] with applications in [[theoretical physics]] and [[topology]]. They are named after [[theoretical physicists]] [[Yang Chen-Ning]] and [[Rodney Baxter]]. These [[mathematical operator\|operators]] are particularly notable for providing solutions to the quantum [[Yang–Baxter equation]], which originated in [[statistical mechanics]], and for their use in constructing [[Knot invariant\|invariants]] of [[knot theory\|knots]], links, and three-dimensional [[manifolds]]. ~~\| Start~~ ~~\| data-sort-value=7032 \| [[Special:Contribs/GregariousMadness\|GregariousMadness]] (7032)~~ \| \|- ~~\| 2025-05-15~~ ~~\| [[Ravenous Abyss]] <small>(2024 EP by Abysmal Oceans)</small>~~ ~~\| ''Ravenous Abyss'' is the debut EP by [[Maldives\|Maldivian]] [[black metal]] band [[Abysmal Oceans]], released on June 8, 2024.~~ ~~\| Start~~ ~~\| data-sort-value=22 \| [[Special:Contribs/SurreaI\|SurreaI]] (22)~~ \| \|- \| 2025-03-09 Line 28 ⟶ 14: \| In [[Kaluza–Klein theory]], a unification of [[general relativity]] and [[electromagnetism]], the five-fimensional Kaluza–Klein–Riemann curvature tensor (or Kaluza–Klein–Riemann–Christoffel curvature tensor) is the generalization of the four-dimensional [[Riemann curvature tensor]] (or Riemann–Christoffel curvature tensor). \| Stub \| data-sort-value=~~3180~~3289 \| [[Special:Contribs/Samuel Adrian Antz\|Samuel Adrian Antz]] (~~3180~~3289) \| \|- Line 35 ⟶ 21: \| The [[Ising model]] is a prototypical model in [[statistical physics]]. The model consists of discrete variables that represent magnetic dipole moments of atomic "spins" that can be in one of two states (+1 or −1). The spins are arranged in a graph, usually a lattice (where the local structure repeats periodically in all directions), allowing each spin to interact with its neighbors. \| C \| data-sort-value=~~902~~1119 \| [[Special:Contribs/Stepwise Continuous Dysfunction\|Stepwise Continuous Dysfunction]] (~~902~~1119) \| \|- ~~\| 2025-06-14~~ ~~\| [[Herschel's condition]] <small>(Optical system example)</small>~~ \| In [[optics]], the Herschel's condition is a condition for an [[optical system]] to produce sharp images for objects over an extended axial range, i.e. for objects displaced along the optical axis. It was formulated by [[John Herschel]]. ~~\| Start~~ ~~\| data-sort-value=104 \| [[Special:Contribs/Sufficient statistics\|Sufficient statistics]] (104)~~ \| \|- ~~\| 2025-02-21~~ ~~\| [[Modular tensor category]]~~ \| A modular tensor category (also called a modular fusion category) is a type of [[tensor category (disambiguation)\|tensor category]] that plays a role in the areas of [[topological quantum field theory]], [[conformal field theory]], and [[quantum algebra]]. Modular tensor categories were introduced in 1989 by the physicists [[Greg Moore (physicist)\|Greg Moore]] and [[Nathan Seiberg]] in the context of [[rational conformal field theory]]. ~~\| B~~ ~~\| data-sort-value=137 \| [[Special:Contribs/Meelo Mooses\|Meelo Mooses]] (137)~~ \| \|- Line 56 ⟶ 28: \| The 1859 City of Adelaide colonial by-election was held on 13 May 1859 to elect one of six members for [[Electoral district of City of Adelaide\|City of Adelaide]] in the [[South Australian House of Assembly]], after sitting member [[William Henville Burford]] resigned on 29 April 1859. \| Stub \| data-sort-value=~~7988~~8043 \| [[Special:Contribs/Milkk7\|Milkk7]] (~~7988~~8043) \| \|- Line 64 ⟶ 36: \| C \| data-sort-value=2829 \| [[Special:Contribs/Faster than Thunder\|Faster than Thunder]] (2829) \| \|- ~~\| 2025-05-21~~ ~~\| [[Quantum circuit cutting]]~~ \| ''Quantum circuit cutting'' is a method to partition a large [[quantum circuit]] into smaller, more manageable parts. In particular, during the [[Noisy intermediate-scale quantum era\|NISQ era]] of [[quantum computing]] the execution of quantum circuits is limited by the size, i.e., number of [[qubit]]s, as well as their high susceptibility to noise. ~~\| C~~ ~~\| data-sort-value=13 \| [[Special:Contribs/Lsherzog1998\|Lsherzog1998]] (13)~~ \| \|- Line 77 ⟶ 42: \| In [[differential geometry]] and in particular [[Yang–Mills theory]], Uhlenbeck's singularity theorem is a result allowing the removal of a [[Singularity (mathematics)\|singularity]] of a [[Four-dimensional Yang–Mills theory\|four-dimensional Yang–Mills]] field with finite energy using gauge. It states as a consequence that Yang–Mills fields with finite energy on flat [[euclidean space]] arise from Yang–Mills fields on the curved [[sphere]], its [[one-point compactification]]. \| Start \| data-sort-value=~~3180~~3289 \| [[Special:Contribs/Samuel Adrian Antz\|Samuel Adrian Antz]] (~~3180~~3289) \| \|- ~~\| 2025-07-07~~ ~~\| [[Quaternion Lorentz Transformations]] <small>(Linear transformation of spacetime coordinates)</small>~~ \| In [[special relativity]], a [[Lorentz transformation]] is a real [[linear transformation]] of the [[spacetime coordinates]] t, x, y, z that preserves the Minkowski invariant or [[spacetime interval]] <math display="block">c^2 \, t^2-x^2-y^2-z^2</math> Using the 4x4 [[metric tensor]] <math>\eta</math>, this is ~~\| C~~ ~~\| data-sort-value=489 \| [[Special:Contribs/DonaldWP\|DonaldWP]] (489)~~ \| \|- Line 92 ⟶ 50: \| C \| data-sort-value=66 \| [[Special:Contribs/PikutaMe\|PikutaMe]] (66) \| \|- \| 2024-01-09 \| [[Ian Smith (civil engineer)]] <small>(Canadian and Swiss civil engineer)</small> \| Ian F. C. Smith is a Canadian and Swiss [[civil engineer]]. He is Emeritus Professor at the [[École Polytechnique Fédérale de Lausanne]] (EPFL) in Switzerland and was the founding director of the [[Nemetschek#Georg_Nemetschek_Institute_-_Artificial_Intelligence_for_the_Built_World\|TUM Georg Nemetschek Institute Artificial Intelligence for the Built World]] at the [[Technical University of Munich]] in Germany. \| Start \| data-sort-value=18 \| [[Special:Contribs/Ronal tarim\|Ronal tarim]] (18) \| \|- \| 2024-01-22 \| [[Silvano Donati]] <small>(Italian physicist in the field of photonics)</small> \| Silvano Donati (born 19 August 1942) is a physicist in the field of [[photonics]]. He is an emeritus professor at the [[University of Pavia]] where he has been Full Professor for 30 years and created the Electro-Optical Engineering Group. \| C \| data-sort-value=35 \| [[Special:Contribs/Fratilias\|Fratilias]] (35) \| \|- \| 2025-07-20 \| [[John Donegan]] <small>(Irish physicist)</small> \| John Donegan is an Irish physicist and academic specializing in photonics, nanophotonics, and optical communications. He is the Professor of Physics and Applications of Light at Trinity College Dublin and Deputy Director of the [[CRANN]] Nanoscience Research Centre having previously served as Head of the School of Physics at Trinity. \| C \| data-sort-value=166 \| [[Special:Contribs/Gukecavoran\|Gukecavoran]] (166) \| \|- \| 2025-08-03 \| [[Dora Reisser]] <small>(British actress (b.1942))</small> \| Dora Reisser (born February 1942) is a former British actress and fashion designer. \| Start \| data-sort-value=16438 \| [[Special:Contribs/Rigg\|Rigg]] (16438) \| \|- \| 2025-07-13 \| [[Gravitational self-force]] <small>(Gravitational self-force formalism)</small> \| In [[gravitational wave]] [[physics]], the gravitational self-force formalism is an approach to solving the [[relativistic two body problem]] using a systematic expansion of the dynamics is powers of the ratio of the masses of the two components of the binary. The gravitational self-force formalism is generally perceived as the only viable route towards predicting accurate gravitational waveform templates for observing [[extreme mass-ratio inspiral]]s with the [[Laser Interferometer Space Antenna]]. \| C \| data-sort-value=15431 \| [[Special:Contribs/TimothyRias\|TimothyRias]] (15431) \| \|- \| 2025-02-21 \| [[Modular tensor category]] <small>(Category theory)</small> \| A modular tensor category (also called a modular fusion category) is a type of [[tensor category (disambiguation)\|tensor category]] that plays a role in the areas of [[topological quantum field theory]], [[conformal field theory]], and [[quantum algebra]]. Modular tensor categories were introduced in 1989 by the physicists [[Greg Moore (physicist)\|Greg Moore]] and [[Nathan Seiberg]] in the context of [[rational conformal field theory]]. \| data-sort-value="A1"\|GA \| data-sort-value=137 \| [[Special:Contribs/Meelo Mooses\|Meelo Mooses]] (137) \| \|- Line 101: \| \|- \| 2025-0607-1627 \| [[~~Amouna~~Dmitry Volkov (physicist)]] <small>(~~2015~~Ukrainian ~~Emirati~~scientist ~~TV series or program~~(1925–1996))</small> \| Dmitry Volkov ({{langx\|uk\|Дмитро Васильович Волков}}; 3 July 1925 – 5 January 1996) — physicist. [[Doctor of Philosophy\|PhD]] in 1956. Doctor of Physical and Mathematical Sciences ([[Habilitation]]) in 1968. Professor (1977). [[Academician]] of [[National Academy of Sciences of Ukraine]] (1988). \| ''Amouna'' (Arabic: أمونة), or alternatively known as Amouna al Mazyouna (Arabic: أمونة المزيونة) is an Emirati children's animated series created by Amer Kokh. It premiered on 25 September 2015 and aired on Majid Kids TV. the series about Amouna is going on a adventure with her brother, Ali and Seif. \| Start \| data-sort-value=5334 \| [[Special:Contribs/~~RobinHarrisonfan2008~~Thrynova\|~~RobinHarrisonfan2008~~Thrynova]] (5334) \| \|- \| 2025-07-2005 \| [[~~John Donegan~~Atominstitute]] <small>(~~Irish~~Austrian University nuclear physics research ~~physicist~~facility)</small> \| The Atominstitute ({{langx\|de\|[[:de:Atominstitut\|Atominstitut]]}}) is an [[Austria\|Austrian]] [[University]] research facility with its own inhouse [[nuclear reactor]] located in [[Vienna]]. The institute most known member is 2022 [[Nobel laureate]] [[Anton Zeilinger]]. \| John Donegan is an Irish physicist and academic specializing in photonics, nanophotonics, and optical communications. He is the Professor of Physics and Applications of Light at Trinity College Dublin and Deputy Director of the [[CRANN]] Nanoscience Research Centre having previously served as Head of the School of Physics at Trinity. \| C \| data-sort-value=~~154~~1274 \| [[Special:Contribs/~~Gukecavoran~~FrankBierFarmer\|~~Gukecavoran~~FrankBierFarmer]] (~~154~~1274) \| \|- \| 2025-01-19 \| [[Fluorescence upconversion]] <small>(Ultrafast laser spectroscopic technique)</small> \| Fluorescence upconversion (FU) is an [[Ultrafast laser spectroscopy\|ultrafast laser spectroscopic]] technique. It is a variant of [[sum-frequency generation]] (of which the [[second-harmonic generation]] (SHG) is a special case) but applied to the detection of the incoherent [[fluorescence]]. It is therefore closely related to the [[Optical Kerr Gating]] (OKG) technique. \| C \| data-sort-value=104 \| [[Special:Contribs/Ozzwah\|Ozzwah]] (104) \| \|- Line 119 ⟶ 126: \| David D. O'Regan is an Irish physicist and professor in physics at [[Trinity College Dublin]], where he leads the Quantum Theory of Materials Research Group. He is also a member of the [[CRANN]] institute, a large centre for nanoscience research at Trinity. \| Start \| data-sort-value=~~154~~166 \| [[Special:Contribs/Gukecavoran\|Gukecavoran]] (~~154~~166) \| \|- \| 2025-0708-2101 \| [[~~Otago~~Stephen ~~Department~~Geoffrey ~~of Physics~~Lipson]] <small>(~~Department in the University of Otago, New~~Israeli ~~Zealand~~physicist)</small> \| Stephen (Geoffrey) Lipson (born 8 January 1941) is an Israeli-British physicist. He is Emeritus Professor of Physics at [[Technion]]. \| The Otago Department of Physics is a physics department located at the [[University of Otago]] in [[Dunedin]], New Zealand. It's specifically situated in the Science 3 building, at the northwest corner of the campus. The building is located at the intersection of Cumberland and St. \| Start \| data-sort-value=~~160~~15 \| [[Special:Contribs/~~Aspir8~~Agent1967\|~~Aspir8~~Agent1967]] (~~160~~15) \| \|- \| 2025-0806-0314 \| [[~~Dora~~Herschel's ~~Reisser~~condition]] <small>(~~British~~Optical ~~actress~~system ~~(b.1942)~~example)</small> \| In [[optics]], the Herschel's condition is a condition for an [[optical system]] to produce sharp images for objects over an extended axial range, i.e. for objects displaced along the optical axis. It was formulated by [[John Herschel]]. ~~\| Dora Reisser (born February 1942) is a former British actress and fashion designer.~~ \| Start \| data-sort-value=~~16127~~115 \| [[Special:Contribs/~~Rigg~~Sufficient statistics\|~~Rigg~~Sufficient statistics]] (~~16127~~115) \| \|- \| 2025-08-0119 \| [[~~Stephen~~Thomas ~~Geoffrey~~L. ~~Lipson~~Gilbert]] <small>(~~Israeli~~American ~~physicist~~scientist (1922–2016))</small> \| Thomas L. Gilbert (November 24, 1922 – May 19, 2016) was an American physicist, a specialist in statistical physics. ~~\| Stephen (Geoffrey) Lipson (born 8 January 1941) is an Israeli-British physicist. He is Emeritus Professor of Physics at [[Technion]].~~ \| Start \| data-sort-value=52574 \| [[Special:Contribs/~~HodLipson2050~~Sunlitsky\|~~HodLipson2050~~Sunlitsky]] (52574) \| \|- \| 2025-0706-2716 \| [[~~Dmitry Volkov (physicist)~~Amouna]] <small>(~~Ukrainian~~2015 ~~scientist~~Emirati ~~(1925–1996)~~TV series or program)</small> \| ''Amouna'' (Arabic: أمونة), or alternatively known as Amouna al Mazyouna (Arabic: أمونة المزيونة) is an Emirati children's animated series created by Amer Kokh. It premiered on 25 September 2015 and aired on [[:ar:قناة_ماجد_للأطفال\|Majid Kids TV]]. the series about Amouna is going on a adventure with her brother, Ali and Seif. \| Dmitry Volkov ({{langx\|uk\|Дмитро Васильович Волков}}; 3 July 1925 – 5 January 1996) — physicist. [[Doctor of Philosophy\|PhD]] in 1956. Doctor of Physical and Mathematical Sciences ([[Habilitation]]) in 1968. Professor (1977). [[Academician]] of [[National Academy of Sciences of Ukraine]] (1988). \| Start \| data-sort-value=3361 \| [[Special:Contribs/~~Thrynova~~RobinHarrisonfan2008\|~~Thrynova~~RobinHarrisonfan2008]] (3361) \| \|- \| 2025-0708-1321 \| [[~~Gravitational~~Shaofan ~~self-force~~Li]] <small>(~~Gravitational self~~Chinese-~~force~~American computational mechanics ~~formalism~~researcher)</small> \| Shaofan Li is a Chinese-American professor of applied and [[computational mechanics]] in the Department of [[Civil and Environmental Engineering]] at the [[University of California, Berkeley]]. \| In [[gravitational wave]] [[physics]], the gravitational self-force formalism is an approach to solving the [[relativistic two body problem]] using a systematic expansion of the dynamics is powers of the ratio of the masses of the two components of the binary. The gravitational self-force formalism is generally perceived as the only viable route towards predicting accurate gravitational waveform templates for observing [[extreme mass-ratio inspiral]]s with the [[Laser Interferometer Space Antenna]]. \| C \| data-sort-value=~~15431~~22 \| [[Special:Contribs/~~TimothyRias~~Yusnadha\|~~TimothyRias~~Yusnadha]] (~~15431~~22) \| \|- \| 2025-0708-1121 \| [[~~Igor~~Yang–Mills ~~Shvets~~moduli space]] <small>(~~Irish~~Moduli space of the Yang–Mills ~~Physicist~~equations)</small> \| In [[gauge theory]], the Yang–Mills moduli space (short YM moduli space, also instanton moduli space) is the [[moduli space]] of the [[Yang–Mills equations]], hence the space of its solutions up to [[gauge]]. It is used in [[Donaldson's theorem]], proven in and improved in , which was listed as a contribution for [[Simon Donaldson]] winning the [[Fields Medal]] in 1986, and to defined the [[Donaldson invariant\|Donaldson invariants]] used to study four-dimensional smooth manifolds (short 4-manifolds). \| Igor Shvets is the Head of Applied Physics at the School of Physics, [[Trinity College Dublin]] (TCD), where he is also a principal investigator at [[CRANN]] and [[AMBER]].. He has worked in nanomaterials, thin-film physics, energy systems, and transparent conducting oxides, and has founded technology spinouts in Ireland. \| ~~Start~~C \| data-sort-value=~~154~~3289 \| [[Special:Contribs/~~Gukecavoran~~Samuel Adrian Antz\|~~Gukecavoran~~Samuel Adrian Antz]] (~~154~~3289) \| \|- \| 2025-07-0507 \| [[~~Atominstitute~~Quaternion Lorentz Transformations]] <small>(~~Austrian University~~Linear ~~nuclear~~transformation ~~physics~~of ~~research~~spacetime ~~facility~~coordinates)</small> \| In [[special relativity]], a [[Lorentz transformation]] is a real [[linear transformation]] of the [[spacetime coordinates]] t, x, y, z that preserves the Minkowski invariant or [[spacetime interval]] <math display="block">c^2 \, t^2-x^2-y^2-z^2</math> Using the 4x4 [[metric tensor]] <math>\eta</math>, this is \| The Atominstitute ({{langx\|de\|[[:de:Atominstitut\|Atominstitut]]}}) is an [[Austria\|Austrian]] [[University]] research facility with its own inhouse [[nuclear reactor]] located in [[Vienna]]. The institute most known member is 2022 [[Nobel laureate]] [[Anton Zeilinger]]. \| C \| data-sort-value=~~1252~~496 \| [[Special:Contribs/~~FrankBierFarmer~~DonaldWP\|~~FrankBierFarmer~~DonaldWP]] (~~1252~~496) \| \|- \| 2025-08-0512 \| [[~~Birman–Schwinger~~Plunging ~~principle~~region]] <small>(~~Eigenvalue~~Region ~~transformation~~just ~~method~~outside event horizons)</small> \| In [[astrophysics]], a plunging region is a region near a [[black hole]] in which [[matter]] can no longer follow [[circular orbits]] and will instead rapidly "plunge" towards the [[event horizon]] at nearly the [[speed of light]]. This region exists between the [[innermost stable circular orbit]] and the event horizon of the black hole. \| In [[mathematics]] the Birman–Schwinger principle is a useful technique to reduce the eigenvalue problem for an unbounded differential operator (such as a [[Schrödinger operator]]) to an eigenvalue problem for a bounded integral operator. It originates from independent work by [[Mikhail Shlyomovich Birman\|M. Sh. Birman]] and [[Julian Schwinger\|J. Schwinger]] in 1961. \| C \| data-sort-value=72988 \| [[Special:Contribs/~~Small epsilon~~Shocksingularity\|~~Small epsilon~~Shocksingularity]] (72988) \| \|} <span style="font-style: italic; font-size: 85%;">Last updated by [[User:SDZeroBot\|SDZeroBot]] <sup>''[[User:SD0001\|operator]] / [[User talk:SD0001\|talk]]''</sup> at 13:4948, 730 August 2025 (UTC)</span>