{"id":18,"date":"2019-01-02T17:04:07","date_gmt":"2019-01-02T19:04:07","guid":{"rendered":"http:\/\/web.vu.lt\/ff\/a.gelzinis\/?page_id=18"},"modified":"2026-04-02T12:44:08","modified_gmt":"2026-04-02T14:44:08","slug":"mokslas","status":"publish","type":"page","link":"http:\/\/web.vu.lt\/ff\/a.gelzinis\/mokslas\/","title":{"rendered":"Mokslas"},"content":{"rendered":"\r\n

Mokslin\u0117s produkcijos s\u0105ra\u0161as Scopus duomen\u0173 baz\u0117je – spauskite \u010dia<\/a>.<\/p>\r\n

Pa\u017eym\u0117tinos mokslin\u0117s publikacijos:<\/p>\r\n

    \r\n
  1. A.\u00a0Gelzinis, L.\u00a0Valkunas, Analytical derivation of equilibrium state for open quantum system<\/a>, J. Chem. Phys. 152<\/strong>, 051103, 2020.
    \u0160iame darbe mes i\u0161ved\u0117me analitin\u0119 i\u0161rai\u0161k\u0105 pusiausvyram redukuotam sistemos tankio operatoriui. M\u016bs\u0173 i\u0161rai\u0161kos galiojimo ribos yra gerokai platesn\u0117s nei skai\u010diavim\u0173, paremt\u0173 \u012fprasta trikd\u017ei\u0173 teorija. Mes \u012fved\u0117me efektin\u0119 rezonansin\u0119 s\u0105veik\u0105 tarp molekulini\u0173 b\u016bsen\u0173, kaip esmin\u012f parametr\u0105 apib\u016bdinant\u012f pusiausvyr\u0105. \u0160i s\u0105veika nuo temperat\u016bros priklauso prie\u0161ingai, nei efektin\u0117 s\u0105veika, apskai\u010diuota remiantis gerai \u017einoma poliarono transformacija, tod\u0117l m\u016bs\u0173 darbas si\u016blo nauj\u0105 po\u017ei\u016br\u012f \u012f pusiausvyros problemas.<\/li>\r\n
  2. Y. Braver, L. Valkunas, A. Gelzinis, Quantum\u2013Classical Approach for Calculations of Absorption and Fluorescence: Principles and Applications,<\/a> J. Chem. Theory Comput. 17<\/strong>, 7157\u20137168, 2021.
    \u0160iame darbe apra\u0161\u0117me teorij\u0105, skirt\u0105 skai\u010diuoti molekulini\u0173 agregat\u0173 sugerties ir fluorescencijos spektrus panaudojant kvantin\u0117s-klasikin\u0117s Liuvilio lygties sprendinius. Iki m\u016bs\u0173 fluorescencijos spektr\u0173 skai\u010diavimai su kvantine-klasikine teorija nebuvo atlikti. Palygin\u0119 spektrus, gautus su \u0161iais metodais, su tiksliais skai\u010diavimais, parod\u0117me, kurie kvantin\u0117s-klasikin\u0117s metodai labiau tinka sugerties, o kurie – fluorescencijos spektrams skai\u010diuoti. Metod\u0173 taikomum\u0105 realioms sistemoms iliustruoja fotosintetinio FMO komplekso spektr\u0173 skai\u010diavimai.<\/li>\r\n
  3. J. Chmeliov, A. Gelzinis, E. Songaila, R. Augulis, C. D. P. Duffy, A. V. Ruban, L. Valkunas, The nature of self-regulation in photosynthetic light-harvesting antenna<\/a>, Nat. Plants 2<\/strong>, 16045, 2016.
    \u0160ioje publikacijoje pristatyti pagrindini\u0173 augal\u0173 \u0161viesorankos kompleks\u0173 (LHCII) agregat\u0173 laikin\u0117s skyros fluorescencijos matavimai, esant pla\u010diam temperat\u016br\u0173 intervalui. Gaut\u0173 rezultat\u0173 analiz\u0117 ir modeliavimas parod\u0117, kad spektruose esant \u017eemoms temperat\u016broms i\u0161ry\u0161k\u0117janti b\u016bsena, atsakinga u\u017e fluorescencij\u0105 ties ~ 700 nm, n\u0117ra susijusi su fluorescencijos gesimu. U\u017e \u0161\u012f gesim\u0105 yra atsakinga tamsin\u0117 b\u016bsena, kurios mikroskopin\u0119 kilm\u0119 lemia nekoherentin\u0117 su\u017eadinimo energijos perna\u0161a i\u0161 chlorofilo \u012f karotenoido molekules. \u0160ie rezultatai paai\u0161kina augaluose stebimo nefotocheminio fluorescencijos gesimo prigimt\u012f.<\/li>\r\n
  4. A. Gelzinis, R. Augulis, C. B\u00fcchell, B. Robert, L. Valkunas, Confronting FCP structure with ultrafast spectroscopy data: evidence for structural variations<\/a>, Phys. Chem. Chem. Phys. 23<\/strong>, 806-821, 2021.
    \u0160iame darbe mes aptar\u0117me ankstesnius FCP kompleks\u0173 2D spektroskopijos rezultatus. Pasinaudodami prie\u0161 kelet\u0105 met\u0173 pasirod\u017eiusiais strukt\u016briniais duomenimis, parod\u0117me, kad \u0161iuo metu \u017einomos FCP strukt\u016bros n\u0117ra pilnai suderinamos su ultraspar\u010diosios spektroskopijos matavimais. Taip pat mes pasi\u016bl\u0117me trimerin\u0119 FCP komplekso i\u0161 titnagdumbli\u0173 Cyclotella Meneghiniana <\/em>(i\u0161 kuri\u0173 ir buvo i\u0161gauti bandiniai 2D spektroskopijos matavimams) strukt\u016br\u0105, kuri yra suderinama su spektroskopiniais ir elektronin\u0117s mikroskopijos matavim\u0173 rezultatais.<\/li>\r\n
  5. A. Gelzinis, R. Augulis, V. Butkus, B. Robert, L. Valkunas, Two-dimensional spectroscopy for non-specialists<\/a>, Biochim. Biophys. Acta 1860<\/strong>, 271-285, 2019.
    \u0160iame straipsnyje mes pateikiame dvimat\u0117s optin\u0117s spektroskopijos apra\u0161ym\u0105, aptardami esmines s\u0105vokas, principus, galimus taikymus ir tik\u0117tinus rezultatus. Dauguma literat\u016broje randam\u0173 ap\u017evalg\u0173 yra pertek\u0119 technini\u0173 detali\u0173, o m\u016bs\u0173 publikacija pateikia supaprastint\u0105, bet d\u0117l to visiems prieinam\u0105, vaizdin\u012f.<\/li>\r\n<\/ol>\r\n

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    Vis\u0173 mokslini\u0173 straipsni\u0173 s\u0105ra\u0161as:<\/p>\r\n\r\n\r\n\r\n

      \r\n
    1. A. Gelzinis, L. Valkunas, Fourth-order complex time-dependent Redfield theory for absorption line shapes<\/a>, J. Chem. Phys. 164<\/strong>, 134107, 2026.<\/li>\r\n
    2. J. Vai\u010daityt\u0117, L. Valkunas, A. Gelzinis, Coupled classical oscillators can exactly mimic dynamics of quantum dimer<\/a>, Phys. Lett. A. 563<\/strong>, 131053, 2025.<\/li>\r\n
    3. R. Jasiunas, V. Ja\u0161inskas, J. Yu, N. Jain, X. Zhou, J. Yuan, R. Zhang, H. Zhang, B. Yang, A. Gelzinis, Y. Zou, V. Gulbinas, F. Gao, Navigating the relationship between voltage losses and efficiency in organic solar cells<\/a>, Org.\u00a0Electron. 140<\/strong>, 107211, 2025.<\/li>\r\n
    4. K. Elhouly, M. Franckevicius, V. Ja\u0161inskas, A. Gel\u017einis, I. Goldberg, R. Gehlhaar, J Genoe, P. Heremans, V. Gulbinas, Transient Photoluminescence Reveals the Dynamics of Injected Charge Carriers in Perovskite Light-Emitting Diodes<\/a>, ACS Appl. Mater. Interfaces 17<\/strong>, 9625\u22129634, 2025.<\/li>\r\n
    5. S. Streckaite, D. Frolov, J. Chmeliov, A. Gelzinis, C Ilioaia, S. Rimsky, R. van Grondelle, L. Valkunas, A. Gall, B. Robert, Single Pixel Reconstruction Imaging: taking confocal imaging to the extreme<\/a>, Lith. J. Phys 64<\/strong>, 259\u2013275, 2024.<\/li>\r\n
    6. J. Vai\u010daityt\u0117, L. Valkunas, A. Gelzinis, Application of the frozen-modes approximation to classical harmonic oscillator systems<\/a>, Lith. J. Phys 64<\/strong>, 162\u2013176, 2024.<\/li>\r\n
    7. G. Rankelyt\u0117, A. Gelzinis, B. Robert, L. Valkunas, J. Chmeliov, Environment-dependent chlorophyll\u2013chlorophyll charge transfer states in Lhca4 pigment\u2013protein complex<\/a>, Front. Plant Sci. 15<\/strong>, 1412750, 2024.<\/li>\r\n
    8. S. Streckaite, C. Ilioaia, I.. Chaussavoine, J. Chmeliov, A. Gelzinis, D. Frolov, L. Valkunas, S. Rimsky, A. Gall, B. Robert, Functional organization of 3D plant thylakoid membranes as seen by high resolution microscopy<\/a>, Biochim. Biophys. Acta-Bioenerg. 1865<\/strong>, 149493, 2024.<\/li>\r\n
    9. S. Barysait\u0117, J. Chmeliov, L. Valkunas, A. Gelzinis, Concentration Quenching of Fluorescence Decay Kinetics of Molecular Systems<\/a>, J. Phys. Chem. B 128<\/strong>, 4887\u20134897, 2024.<\/li>\r\n
    10. A. Gelzinis, J. Chmeliov, M. Tutkus, E. Vitulskien\u0117, M. Franckevi\u010dius, C. B\u00fcchel, B. Robert, L. Valkunas, Fluorescence quenching in aggregates of fucoxanthin\u2013chlorophyll protein complexes: Interplay of fluorescing and dark states<\/a>, Biochim. Biophys. Acta-Bioenerg. 1865<\/strong>, 149030, 2024.<\/li>\r\n
    11. J. Tamo\u0161i\u016bnait\u0117, S. Streckait\u0117, J. Chmeliov, L. Valkunas, A. Gelzinis, Concentration quenching of fluorescence in thin films of zinc-phthalocyanine<\/a>, Chem. Phys. 572<\/strong>, 111949, 2023.<\/li>\r\n
    12. A. Dementjev, V. Dudoitis, A. Gelzinis, O. Gylien\u0117, R. Binkien\u0117, D. Jasinevi\u010dien\u0117, V. Ulevi\u010dius, The CARS microscopy application for determination of the deacetylation degree in chitin and chitosan species<\/a>, J. Raman Spectrosc. 54<\/strong>, 524\u2013531, 2023.<\/li>\r\n
    13. P. Juknevicius, J. Chmeliov, L. Valkunas, A. Gelzinis, Application of artificial neural networks for modeling of electronic excitation dynamics in 2D lattice: Direct and inverse problems<\/a>, AIP Advances 13<\/strong>, 035224, 2023.<\/li>\r\n
    14. V. Ja\u0161inskas, M. Franckevi\u010dius, A. Gel\u017einis, J. Chmeliov, V. Gulbinas, Direct Tracking of Charge Carrier Drift and Extraction from Perovskite Solar Cells by Means of Transient Electroabsorption Spectroscopy<\/a>, ACS Appl. Electron. Mater. 5<\/strong>, 317\u2212326, 2023.<\/li>\r\n
    15. R. Jasi\u016bnas, H. Zhang, A. Gel\u017einis, J. Chmeliov, M. Franckevi\u010dius, F. Gao, V. Gulbinas, Interplay between charge separation and hole back transfer determines the efficiency of non-fullerene organic solar cells with low energy level offset<\/a>, Org. Electron. 108<\/strong>, 106601, 2022.<\/li>\r\n
    16. A. Mikal\u010di\u016bt\u0117, A. Gelzinis, M. Ma\u010dernis, C. B\u00fcchell, B. Robert, L. Valkunas, J. Chmeliov, Structure-based model of fucoxanthin\u2013chlorophyll protein complex: Calculations of chlorophyll electronic couplings<\/a>, J. Chem. Phys. 156<\/strong>, 234101, 2022.<\/li>\r\n
    17. Y. Braver, L. Valkunas, A. Gelzinis, Stark absorption and Stark fluorescence spectroscopies: Theory and simulations<\/a>, J. Chem. Phys. 155<\/strong>, 244101, 2021.<\/li>\r\n
    18. J. Chmeliov, K. Elkhouly, R. Gegevi\u010dius, L. Jonu\u0161is, A. Devi\u017eis, A. Gel\u017einis, M. Franckevi\u010dius, I. Goldberg, J. Hofkens, P. Heremans, W. Qiu, V. Gulbinas, Ion Motion Determines Multiphase Performance Dynamics of Perovskite LEDs<\/a>, Adv. Opt. Mater. 9<\/strong>, 2101560, 2021.<\/li>\r\n
    19. Y. Braver, L. Valkunas, A. Gelzinis, Quantum\u2013Classical Approach for Calculations of Absorption and Fluorescence: Principles and Applications,<\/a> J. Chem. Theory Comput. 17<\/strong>, 7157\u20137168, 2021.<\/li>\r\n
    20. Y. Braver, L. Valkunas, A. Gelzinis, Derivation of the stationary fluorescence spectrum formula for molecular systems from the perspective of quantum electrodynamics<\/a>, Lith. J. Phys. 61<\/strong>, 110\u201313, 2021<\/li>\r\n
    21. A. Devi\u017eis, A. Gelzinis, J. Chmeliov, M Diethelm, L. Endriukaitis, D. Padula, R. Hany, Carrier Tunneling from Charge Transfer States in Organic Photovoltaic Cells<\/a>, Adv. Funct. Mater. 31<\/strong>, 2102000, 2021.<\/li>\r\n
    22. A. Fakharuddin, M. Franckevi\u010dius, A. Devi\u017eis, A. Gel\u017einis, J. Chmeliov, P. Heremens, V. Gulbinas, Double Charge Transfer Dominates in Carrier Localization in Low Bandgap Sites of Heterogeneous Lead Halide Perovskites<\/a>, Adv. Funct. Mater. 31<\/strong>, 2010076, 2021.<\/li>\r\n
    23. A. Gelzinis, R. Augulis, C. B\u00fcchell, B. Robert, L. Valkunas, Confronting FCP structure with ultrafast spectroscopy data: evidence for structural variations<\/a>, Phys. Chem. Chem. Phys. 23<\/strong>, 806-821, 2021.<\/li>\r\n
    24. V.\u00a0Mascoli, A.\u00a0Gelzinis, J.\u00a0Chmeliov, L.\u00a0Valkunas, R.\u00a0Croce, Light-harvesting complexes access analogue emissive states in different environments<\/a>, Chem. Sci. 11<\/strong>, 5697\u20135709, 2020.<\/li>\r\n
    25. Y.\u00a0Braver, L.\u00a0Valkunas, A.\u00a0Gelzinis, Benchmarking the forward\u2013backward trajectory solution of the quantum-classical Liouville equation<\/a>, J. Chem. Phys. 152<\/strong>, 214116, 2020.<\/li>\r\n
    26. A.\u00a0Gelzinis, L.\u00a0Valkunas, Analytical derivation of equilibrium state for open quantum system<\/a>, J. Chem. Phys. 152<\/strong>, 051103, 2020.<\/li>\r\n
    27. J. Chmeliov, A. Gelzinis, M. Franckevi\u010dius, M. Tutkus, F. Saccon, A. V. Ruban, L. Valkunas, Aggregation-Related Nonphotochemical Quenching in the Photosynthetic Membrane<\/a>, J. Phys. Chem. Lett. 10<\/strong>, 7340\u20137346, 2019.<\/li>\r\n
    28. Y. Braver, A. Gelzinis, J. Chmeliov, L. Valkunas, Application of decay- and evolution-associated spectra for molecular systems with spectral shifts or inherent inhomogeneities<\/a>, Chem. Phys. 525<\/strong>, 110403, 2019.<\/li>\r\n
    29. A. Gelzinis, R. Augulis, V. Butkus, B. Robert, L. Valkunas, Two-dimensional spectroscopy for non-specialists<\/a>, Biochim. Biophys. Acta 1860<\/strong>, 271-285, 2019.<\/li>\r\n
    30. A. Gelzinis, Y. Braver, J. Chmeliov, L. Valkunas, Decay- and evolution-associated spectra of time-resolved fluorescence of LHCII aggregates<\/a>, Lith. J. Phys. 58<\/strong>, 295-306, 2018.<\/li>\r\n
    31. E. Rybakovas, A. Gelzinis, L. Valkunas, Simulations of absorption and fluorescence lineshapes using the reaction coordinate method<\/a>, Chem. Phys. 515<\/strong>, 242\u2013251, 2018.<\/li>\r\n
    32. A. Gelzinis, J. Chmeliov, A. V. Ruban, L. Valkunas, Can red-emitting state be responsible for fluorescence quenching in LHCII aggregates?<\/a>, Phot. Res. 135<\/strong>, 275\u2013284, 2018.<\/li>\r\n
    33. A. Gelzinis, E. Rybakovas, L. Valkunas, Applicability of transfer tensor method for open quantum system dynamics<\/a>, J. Chem. Phys. 147<\/strong>, 234108, 2017.<\/li>\r\n
    34. A. Gelzinis, D. Abramavicius, J. P. Ogilvie, L. Valkunas, Spectroscopic properties of photosystem II reaction center revisited<\/a>, J. Chem. Phys. 147<\/strong>, 115102, 2017.<\/li>\r\n
    35. J. Pan, A. Gelzinis, V. Choro\u0161ajev, M. Vengris, S. Seckin Senlik, J.-R. Shen, L. Valkunas, D. Abramavicius, J. P. Ogilivie, Ultrafast energy transfer within the photosystem II core complex<\/a>, Phys. Chem. Chem. Phys. 19<\/strong>, 15356-15367, 2017.<\/li>\r\n
    36. V. Choro\u0161ajev, A. Gelzinis, L. Valkunas, D. Abramavicius, Benchmarking the stochastic time-dependent variational approach for excitation dynamics in molecular aggregates<\/a>, Chem. Phys. 481<\/strong>, 108-116, 2016.<\/li>\r\n
    37. J. Chmeliov, A. Gelzinis, E. Songaila, R. Augulis, C. D. P. Duffy, A. V. Ruban, L. Valkunas, The nature of self-regulation in photosynthetic light-harvesting antenna<\/a>, Nat. Plants 2<\/strong>, 16045, 2016.<\/li>\r\n
    38. A. Gelzinis, D. Abramavicius, L. Valkunas, Absorption lineshapes of molecular aggregates revisited<\/a>, J. Chem. Phys. 142<\/strong>, 154107, 2015.<\/li>\r\n
    39. V. Butkus, A. Gelzinis, R. Augulis, A. Gall, C. B\u00fcchell, B. Robert, D. Zigmantas, L. Valkunas, D. Abramavicius, Coherence and population dynamics of chlorophyll excitations in FCP complex: Two-dimensional spectroscopy study<\/a>, J. Chem. Phys. 142<\/strong>, 212414, 2015.<\/li>\r\n
    40. A. Gelzinis, V. Butkus, E. Songaila, R. Augulis, A. Gall, C. B\u00fcchell, B. Robert, D. Abramavicius, D. Zigmantas, L. Valkunas, Mapping energy transfer channels in fucoxanthin-chlorophyll protein complex<\/a>, Biochim. Biophys. Acta 1847<\/strong>, 241-247, 2015.<\/li>\r\n
    41. F. D. Fuller, J. Pan, A. Gelzinis, V. Butkus, S. S. Senlik, D. E. Wilcox, C. F. Yocum, L. Valkunas, D. Abramavicius, J. P. Ogilvie, Vibronic coherence in oxygenic photosynthesis<\/a>, Nat. Chem. 6<\/strong>, 706-711, 2014.<\/li>\r\n
    42. V. Choro\u0161ajev, A. Gelzinis, L. Valkunas, D. Abramavicius, Dynamics of exciton-polaron transition in molecular assemblies: The variational approach<\/a>, J. Chem. Phys. 140<\/strong>, 244108, 2014.<\/li>\r\n
    43. E. Songaila, R. Augulis, A. Gelzinis, V. Butkus, A. Gall, C. B\u00fcchell, B. Robert, D. Zigmantas, D. Abramavicius, L. Valkunas, Ultrafast Energy Transfer from Chlorophyll\u00a0c2<\/sub> to Chlorophyll\u00a0a in Fucoxanthin-Chlorophyll Protein Complex<\/a>, J. Phys. Chem. Lett. 4<\/strong>, 3590-3595, 2013.<\/li>\r\n
    44. A. Gelzinis, L. Valkunas, F. D. Fuller, J. P. Ogilvie, S. Mukamel, D. Abramavicius, Tight-binding model of the photosystem II reaction center: application to two-dimensional electronic spectroscopy<\/a>, New J. Phys. 15<\/strong>, 075013, 2013.<\/li>\r\n
    45. V. Balevi\u010dius Jr., A. Gelzinis, D. Abramavicius, L. Valkunas, Excitation Energy Transfer and Quenching in a Heterodimer: Applications to the Carotenoid-Phthalocyanine Dyads<\/a>, J. Phys. Chem. B 117<\/strong>, 11031-11041, 2013.<\/li>\r\n
    46. V. Balevi\u010dius Jr., A. Gelzinis, D. Abramavicius, T. Man\u010dal, L. Valkunas, Excitation dynamics and relaxation in a molecular heterodimer<\/a>, Chem. Phys. 404<\/strong>, 94-102, 2012.<\/li>\r\n
    47. A. Gelzinis, D. Abramavicius, L. Valkunas, Non-Markovian effects in time-resolved fluorescence spectrum of molecular aggregates: tracing polaron formation<\/a>, Phys. Rev. B 84<\/strong>, 245430, 2011.<\/li>\r\n
    48. V. Butkus, A. Gelzinis, L. Valkunas, Quantum coherence and disorder-specific effects in simulations of 2D spectra of one-dimensional J-aggregates<\/a>, J. Phys. Chem. A 115<\/strong>, 3876-3885, 2011.<\/li>\r\n
    49. V. Butkus, D. Abramavicius, A. Gelzinis, L Valkunas, Two-dimensional optical spectroscopy of molecular aggregates<\/a>, Lith. J. Phys. 50<\/strong>, 267-303, 2010.<\/li>\r\n<\/ol>\r\n","protected":false},"excerpt":{"rendered":"

      Mokslin\u0117s produkcijos s\u0105ra\u0161as Scopus duomen\u0173 baz\u0117je – spauskite \u010dia. Pa\u017eym\u0117tinos mokslin\u0117s publikacijos: A.\u00a0Gelzinis, L.\u00a0Valkunas, Analytical derivation of equilibrium state for open quantum system, J. Chem. Phys. 152, 051103, 2020.\u0160iame darbe mes i\u0161ved\u0117me analitin\u0119 i\u0161rai\u0161k\u0105 pusiausvyram redukuotam sistemos tankio operatoriui. M\u016bs\u0173 i\u0161rai\u0161kos galiojimo ribos yra gerokai platesn\u0117s nei skai\u010diavim\u0173, paremt\u0173 \u012fprasta trikd\u017ei\u0173 teorija. Mes \u012fved\u0117me efektin\u0119 […]<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"footnotes":""},"class_list":["post-18","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"http:\/\/web.vu.lt\/ff\/a.gelzinis\/wp-json\/wp\/v2\/pages\/18","targetHints":{"allow":["GET"]}}],"collection":[{"href":"http:\/\/web.vu.lt\/ff\/a.gelzinis\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"http:\/\/web.vu.lt\/ff\/a.gelzinis\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"http:\/\/web.vu.lt\/ff\/a.gelzinis\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"http:\/\/web.vu.lt\/ff\/a.gelzinis\/wp-json\/wp\/v2\/comments?post=18"}],"version-history":[{"count":54,"href":"http:\/\/web.vu.lt\/ff\/a.gelzinis\/wp-json\/wp\/v2\/pages\/18\/revisions"}],"predecessor-version":[{"id":789,"href":"http:\/\/web.vu.lt\/ff\/a.gelzinis\/wp-json\/wp\/v2\/pages\/18\/revisions\/789"}],"wp:attachment":[{"href":"http:\/\/web.vu.lt\/ff\/a.gelzinis\/wp-json\/wp\/v2\/media?parent=18"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}