{"id":18,"date":"2015-09-05T02:19:27","date_gmt":"2015-09-05T02:19:27","guid":{"rendered":"http:\/\/blogs.scu.edu\/etillman\/?page_id=18"},"modified":"2025-01-06T20:23:52","modified_gmt":"2025-01-06T20:23:52","slug":"publications","status":"publish","type":"page","link":"https:\/\/blogs.scu.edu\/etillman\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"

Refereed Publications (*indicates student coauthor)<\/strong><\/p>\n

From SCU<\/strong><\/h2>\n

49)\u00a0 <\/strong>Chong, J. L.*<\/span>,\u00a0Burch, A. M.*<\/span>, Otero, D. M.*<\/span>,\u00a0Tillman, E. S.<\/strong>\u00a0 “Room Temperature Nickel-catalyzed Reductive Coupling of End-brominated Polystyrene Chains” <\/span>\u00a0Journal of Polymer Science Part A, Polymer Chemistry <\/em>2024<\/strong>, 62<\/em>, 146 – 152.\u00a0 https:\/\/doi.org\/10.1002\/pol.20230620<\/a><\/p>\n

48)\u00a0<\/strong> Basler, E. D.*<\/span>,\u00a0Chong, J. L.*<\/span>,\u00a0Heath, C. M.*<\/span>,\u00a0Ching, K. S.*<\/span>,\u00a0Jennett, S. T.*<\/span>,\u00a0Tillman, E. S.<\/span><\/strong>,\u00a0Nickel-Catalyzed Reductive Homodimerization of Brominated Polystyrene Chains<\/span>.\u00a0Macromol. Chem. Phys.<\/i>\u00a02022<\/span><\/strong>, 2200320.
\nhttps:\/\/doi.org\/10.1002\/macp.202200320<\/a><\/p>\n

47) <\/strong>Andry, J.J.*; Lee, J.L.*; Wu, J.P.*; Xia, K.*; Tillman, E.S. <\/strong>\u201cUniversal Chain-End Coupling Conditions for Polystyrene, Polyacrylate, and Polymethacrylate Radicals\u201d Processes <\/em>2021, <\/strong>9, <\/em>1001. https:\/\/doi.org\/10.3390\/pr9061001<\/a><\/p>\n

46)<\/strong> Xia, K.*; Rubaie, A.J.*; Johnson, B.P.*; Tillman, E.S. <\/strong>\u201cGreener Coupling of Poly(methyl methacrylate) and Poly(methyl acrylate) Chains Using Activators Generated by Electron Transfer and Radical Traps\u201d Macromolecular Chemistry and Physics <\/em>2020,<\/strong> 221<\/span>, 2000125.https:\/\/doi.org\/10.1002\/macp.202000125<\/a><\/strong><\/p>\n

45)<\/strong> Ching, M.E.*; Lee, J.J.*; Wu, J.P.* Tillman, E.S.<\/strong> \u201cEffect of Aromatic Co-solvents on the Efficiency of Atom Transfer Radical Coupling Reactions of Fluorinated and non-Fluorinated Vinyl Aromatic Polymers\u201d Macromolecular Chemistry and Physics <\/em>2019<\/strong>, 220, 12, 1900319.<\/em><\/p>\n

\u00a0<\/strong>44)<\/strong> Xia, K.*; Rubaie, A.J.*; Johnson, B.P.*; Parker, S.A.*; Tillman, E.S.<\/strong> \u201cAtom Transfer Coupling Reactions Performed with Benign Reducing Agents and Radical Traps\u201d Journal of Polymer Science Part A, Polymer Chemistry <\/em>2019<\/strong>, 57, <\/em>2113\u20132120.\u00a0\u00a0https:\/\/doi.org\/10.1002\/pola.29482<\/p>\n

43)<\/strong>\u00a0Heiler, K.E.*; Pan, C.W.*; Heiler, A.J.*;Wu, J.P.* Tillman, E.S.\u00a0“Synthesis of Nitroxide End-Labeled Polymers By Capturing Polystyrene Radicals with Spin Traps”\u00a0 Macromolecular Chemistry and Physics<\/em>\u00a02018<\/strong>,1800171<\/em>.\u00a0\u00a0https:\/\/doi.org\/10.1002\/macp.201800171<\/a><\/p>\n

42)<\/strong> Pan, C.W.*; Xia, K.*; Parker, S.A.*; Tillman, E.S.\u00a0“Identity of Low Molecular Weight Species Formed in End-to-End Cyclization Reactions Performed in THF”\u00a0 Polymers<\/em> 2018<\/strong>,10(8), 844.\u00a0\u00a0https:\/\/doi.org\/10.3390\/polym10080844<\/a><\/p>\n

41)<\/strong> Pan, C.W.*; Tillman, E.S.\u00a0“Accurately Determining the Extent of Coupling in Post-polymerization Reactions of Polystyrene”\u00a0 Polymers<\/em> 2018<\/strong>,10, 80; doi:10.3390\/polym10010080<\/a><\/p>\n

40) <\/strong><\/strong>Wu, J.P.*<\/span>; Pan, C.W.*; <\/span><\/span>Heiler, K.E.*; Ching, M.E.*; Tillman, E.S. \u201cAltering the Effectiveness of Radical Traps in Atom Transfer Radical Coupling Reactions of Polymer Chains\u201d <\/span>Polymer <\/em>2017<\/strong>, <\/strong>127, 66-76. \u00a0https:\/\/doi.org\/10.1016\/j.polymer.2017.08.046<\/a><\/span><\/p>\n

39) <\/strong><\/strong>Arce, M.M.*; Pan, C.W.*; Thursby, M.M.*; Wu, J.P.*;\u00a0Carnicom, E.M..*; Tillman, E.S. “Influence of Solvent on Radical Trap-Assisted Dimerization and Cyclization of Polystyrene Radicals”\u00a0Macromolecules<\/em> 2016<\/strong>, 49<\/em>, 7804-7813. DOI:10.1021\/acs.macromol.6b01794<\/a><\/span><\/p>\n

38)<\/strong> <\/strong>McFadden, B.*; Arce, M.M.*; Abrusezze, J.*; Herman, J.*; Carnicom, E.M..*; Tillman, E.S.\u201dRadical Trap-Assisted Atom Transfer Radical Coupling of Diblock Copolymers as a Method of Forming Triblock Copolymers\u201d Macromolecular Chemistry and Physics<\/em>\u00a02016, <\/strong>217<\/em>, 2473-2482.\u00a0DOI:<\/span> 10.100\/<\/span><\/span>macp<\/span>.201600317<\/span><\/span><\/span><\/a><\/span><\/p>\n

From Bucknell<\/strong><\/h2>\n

37)<\/strong>\u00a0Blackburn, S.C.*; Myers, K.D.*;Tillman, E.S.<\/span>\u00a0<\/b>\u201cMacrocyclic Poly(methyl acrylate) and Macrocyclic Poly(methyl acrylate-block-styrene) Synthesized by Radical Trap-assisted Atom Transfer Radical Coupling\u00a0Polymer\u201d <\/span>Polymer\u00a0<\/i>2015<\/strong>,<\/span>\u00a0216, <\/i>1282-1290.<\/span><\/p>\n

36)<\/strong>\u00a0Blackburn, S.C.*; Tillman, E.S.\u00a0<\/b>\u201cSynthesis of Cyclic Poly(methyl methacrylate) Directly from Dihalogenated Linear Precursors\u00a0\u201dMacromolecular Chemistry and Physics<\/i>\u00a02015<\/strong>,\u00a068, <\/i>284-292.<\/p>\n

35)<\/strong>\u00a0Carnicom, E.M.*; Abrusseze J.A..*;\u00a0Sidibe, Y.*; Myers, K.D.*;\u00a0Tillman, E.S.\u00a0<\/b>\u201cEffect of Trapping Agent and Polystyrene Chain End\u00a0Functionality on Radical Trap-Assisted Atom Transfer Radical Coupling \u201d\u00a0Polymers<\/em>\u00a02014<\/strong>,\u00a06<\/i>, 2737-2751.<\/p>\n

34)<\/strong>\u00a0Valente, C.J.*; Schellenberger, A.M.*;\u00a0<\/b>Tillman, E.S.\u00a0<\/b>\u201cDimerization of Poly(methyl methacrylate) Chains Using Radical Trap-Assisted Atom Transfer Radical Coupling\u201d\u00a0Macromolecules<\/em>\u00a02014<\/strong>,\u00a047<\/i>, 2226-2232.<\/p>\n

33)<\/strong>\u00a0Carnicom, E.M.*; Tillman, E.S. \u201cPolymerization of Styrene and Cyclization to Macrocyclic Polystyrene in a One-pot, Two-Step Sequence\u201d\u00a0Reactive and Functional Polymers\u00a0<\/em>2014<\/strong>, 80, 9-14. \u00a0<\/em><\/p>\n

32)<\/strong>\u00a0<\/b>Carnicom, E.M.*; Coyne, W.E.*; Myers, K.D.*;\u00a0Tillman, E.S.\u00a0 \u201cOne Pot, Two Step Sequence Converting Atom Transfer Radical Polymerization Directly to Radical Trap-Assisted Atom Transfer Radical Coupling\u201d Polymer,<\/em>\u00a02013<\/b>, 54<\/em>,\u00a05560-5567.<\/p>\n

31)<\/strong>\u00a0<\/b>Butcher, W.E.*;\u00a0Radzinski, S.C.*; \u00a0Tillman, E.S.; \u00a0\u201cSelective Formation of Diblock Copolymers Using Radical Trap-Assisted Atom Transfer Radical Coupling\u201d\u00a0Journal of Polymer Science Part A: Polymer Chemistry<\/i>\u00a02013<\/b>, 51<\/em>, \u00a03619-3626.<\/p>\n

30)<\/strong>\u00a0<\/b>Voter, A.F.*; Tillman, E.S.; Findeis, P.;\u00a0Radzinski, S.C.*;\u00a0 \u201cSynthesis of Macrocyclic Polymers Formed via Intramolecular Radical Trap-Assisted Atom Transfer Radical Coupling\u201d ACS\u00a0<\/em>Macro Letters<\/i>\u00a02012<\/b>,\u00a01, <\/i>1066-1070.<\/p>\n

29)<\/strong>\u00a0<\/b>Pickett, P.D.*;\u00a0Radzinski, S.C.*;\u00a0Tillman, E.S.\u00a0\u201cProbing the Effects of Pi-pi Stacking on the Controlled Radical Polymerization of Styrene and Fluorinated Styrene\u201d\u00a0Journal of Polymer Science Part A: Polymer Chemistry<\/i>\u00a02012<\/b>,\u00a01, <\/i>156-165.<\/p>\n

28)<\/b> Radzinski, S.C.*; Tillman, E.S.; \u201cTrapping Polystyrene Radicals With Nitrones:\u00a0 Synthesis of Polymers With Mid-Chain Alkoxyamine Functionality\u201d Polymer<\/em>\u00a02011<\/strong>,\u00a052, <\/em>6003-6010.<\/em><\/p>\n

27) <\/strong>Butcher, W.E.*; Tillman, E.S.\u00a0 \u201c<\/strong>Hydrogen Abstraction Followed by Nitroxide Mediated Polymerization: \u00a0Synthesis of 2,7-Dibromofluorene-Labeled Polystyrene\u201d Macromolecular Chemistry and Physics <\/i>2011<\/b>, 212,<\/i> 2224-2233.<\/i><\/p>\n

26)<\/strong>\u00a0<\/b>Pickett, P.D.*; Tillman, E.S.;\u00a0Voter, A.F.*\u00a0\u201cEffect of Pi-pi Stacking on the Atom Transfer Radical Polymerization of Styrene\u201dPolymer<\/em>\u00a02011<\/strong>,\u00a052<\/em>, 55-62.<\/p>\n

25) <\/strong>Richard, M.E.*;\u00a0Reese, K.P.*;\u00a0Stone, J.J.*;\u00a0Pickett, P.D.*;\u00a0Tillman, E.S.; Stockland Jr., R.A. \u201cProbing the Steric Limits of Rhodium Catalyzed Hydrophosphinylation.\u00a0 E-H addition vs. Dimerization\/Oligomerization\/Polymerization\u201d\u00a0Journal of Organometallic Chemistry<\/em>\u00a02011<\/strong>,\u00a0696<\/em>, 123-129.<\/p>\n

24)<\/strong>\u00a0Voter, A.F.*;\u00a0<\/b>Tillman, E.S.\u00a0<\/b>\u201cAn Easy and Efficient Route to Macrocyclic Polymers Via Intramolecular Radical-Radical Coupling of Chain Ends\u201d\u00a0Macromolecules<\/em>\u00a02010<\/strong>,\u00a0<\/i>43<\/em>, 10304-10310.<\/p>\n

23)<\/strong>\u00a0<\/b>Domingues, K.D.*;\u00a0Tillman, E.S.\u00a0\u201cRadical-radical Coupling of Polystyrene Chains Using AGET ATRP\u201d\u00a0Journal<\/em>\u00a0Polymer Science Part A: Polymer Chemistry<\/em>\u00a0<\/i>2010<\/strong>,\u00a0<\/i>48,<\/em>\u00a0<\/i>5737-5745.<\/p>\n

22)<\/b> Leasure, J.G.*; Tillman, E.S., Brinkman, C.E.*; Monk, I.W.*; Cohen, N.A.* \u201cEffect of Temperature, Solvent, Lewis Acid, and Additives on the Polymerization of tert<\/i>-Butyl Vinyl Ether Using Lewis Acid-induced N<\/i>-Methyleneamines as Cationic Initiators\u201d Polymer<\/i>International <\/i>2010<\/b>, 59, <\/i>642-647.<\/p>\n

21)<\/b> Contrella, N.D.*; Tillman, E.S. \u201cSequential Anionic and Reverse Atom Transfer Radical Polymerizations From a Single Carbon: \u00a0Synthesis of Polystyrene-block-Poly(methyl methacrylate)\u201d Macromolecular Chemistry and Physics <\/i>2009<\/b>, 210, <\/i>2167-2173.<\/i><\/p>\n

20) <\/b>Cohen, N.A.*; Tillman, E.S., Thakur, S.*; Smith, J.R.*; Eckenhoff, W.T.; Pintauer, T. \u201cEffect of the Ligand in Atom Transfer Radical Polymerization Reactions Initiated By Photodimers of 9-Bromoanthracene\u201d Macromolecular Chemistry and Physics<\/i> 2009<\/b>, 210<\/i>, 163-168.<\/p>\n

19) <\/b>Tillman, E.S.; Contrella, N.D.*; Leasure, J.G.* \u201cMonitoring the Nitroxide Mediated Polymerization of Styrene Using Gel Permeation Chromatography and Proton NMR\u201d Journal of Chemical Education <\/i>2009<\/b>, 86, <\/i>1424-1426.<\/p>\n

18)<\/b> Thakur, S.*; Smith, J.R.*; Tillman, E.S.; Cohen, N.A.*; Contrella, N.D.* \u201c9-Bromoanthracene Photodimers as Initiators in Controlled Radical Polymerization: Silane Radical Atom Abstraction Coupled with Nitroxide Mediated Polymerization\u201d Journal of Polymer Science, Part A: Polymer Chemistry<\/i> 2008<\/b>, 46<\/i>, 6016-6022.<\/p>\n

17) <\/b>Contrella, N.D.*; Tillman, E.S. \u201cSynthesis and Characterization of Fluorene-labeled Polymers Prepared By Nitroxide Mediated Polymerization \u201d Polymer<\/i> 2008<\/b>, 49, <\/i>4076-4079.<\/p>\n

16) <\/b>Thakur, S.*; Cohen, N.A.*; Tillman, E.S.<\/strong> \u201cChain Extension and Block Copolymer Synthesis Using Silane Radical Atom Abstraction Coupled with Nitroxide Mediated Polymerization\u201d Polymer<\/i> 2008<\/b>,49, <\/i>1483-1489.<\/p>\n

15)<\/b> Tillman, E.S.; Miller, D.J.*; Roof, A.C.* \u201cPhotodimers of 9-Haloanthracenes as Initiators in Atom Transfer Radical Polymerization:\u00a0 Effect of the Bridgehead Halogen\u201d Polymer Bulletin<\/i> 2007, <\/b>58<\/i>, 881-891.<\/p>\n

14) <\/b>Thakur, S.*; Tillman, E.S. \u201cEfficient Metal-free Coupling of Polystyrene Chains Using Silane Radical Atom Abstraction\u201d Journal of Polymer Science Part A, Polymer Chemistry<\/i> 2007<\/b>, 45<\/i>, 3488-3493.<\/p>\n

13)<\/b> McKnight, J.N.*; Tillman, E.S.; Sarry, L.R.* \u201cLewis Acid-Induced N<\/i>-methyleneamines as Initiators in the Synthesis of Secondary Amine-Terminated Polymers\u201d Macromolecular Rapid Communications<\/i> 2006<\/b>, 27<\/i>, 1578-1583.<\/p>\n

12)<\/b> Tillman, E.S.; Roof, A.C.*; Palmer, S.M.*; Zarko, B.A.*; Goodman, C.C.*; Roland, A.M.* \u201cSynthesis of Chromophore-labeled Polymers and their Molecular Weight Determination Using UV-Vis Spectroscopy\u201d Journal of Chemical Education <\/i>2006<\/b>, 83, <\/i>1215-1217.<\/p>\n

11) <\/b>Roof, A.C.*; Tillman, E.S.; Malik, R.E.*; Roland, A.M.*; Miller, D.J.*; Sarry, L.R.* \u201cMechanistic Investigation of 9-Bromoanthracene Photodimers as Initiators in Atom Transfer Radical Polymerization\u201d Polymer<\/i> 2006<\/b>, 47<\/i>, 3325-3335.<\/p>\n

10)<\/b> Ludwig, B.*;\u00a0Tillman, E.S. \u201cPolystyrene End-labeled with 2,7-Dibromofluorene Synthesized Using an Adaptation of Reverse Atom Transfer Radical Polymerization\u201d Macromolecular Chemistry and Physics<\/i> 2005<\/b>, 206<\/i>, 2143-2152.<\/p>\n

9)<\/b> Goodman, C.C.*; Roof, A.C.*; Tillman, E.S.; Ludwig, B.*; Chon, D.*; Weigley, M. I.* \u201cSynthesis and Characterization of Fluorene End-Labeled Polystyrene with Atom Transfer Radical Polymerization\u201d Journal of Polymer Science Part A, Polymer Chemistry <\/i>2005,<\/b>43<\/i>,2657-2665.<\/p>\n

8)<\/b> Stone, J.J.*;<\/i> Stockland Jr., R.A.; Reyes Jr., J.M; Kovach, J.*; Goodman, C.C.*; Tillman, E.S. \u201cMicrowave-assisted Solventless Single and Double Addition of HP(O)Ph2<\/sub> to Alkynes\u201d\u00a0 Journal of Molecular Catalysis A: Chemistry <\/i>2005<\/b>, 226<\/i>, 11-21.<\/p>\n

From PhD and Postdoctoral Work<\/strong><\/h2>\n

7)<\/b> Gao, T.;\u00a0Tillman, E.S.;\u00a0Lewis\u00a0,\u00a0N.S.\u00a0\u201cDetection and Classification of Volatile Organic Amines and Carboxylic Acids Using Arrays of Carbon Black-Dendrimer Composite Vapor Detectors\u201d\u00a0Chemistry of Materials<\/i>\u00a02005<\/strong>,\u00a017<\/em>, 2904-2911.<\/p>\n

6) <\/b>Tillman, E.S.;\u00a0Lewis\u00a0,\u00a0N.S.\u00a0\u201cMechanism of Enhanced Sensitivity Response of Linear Poly(ethyleneimine)-Carbon Black Composite Detectors to Carboxylic Acid Vapors\u201d\u00a0<\/i>Sensors and Actuators: B\u00a0\u00a0<\/i>2003,\u00a0<\/i><\/b>1-2,\u00a0<\/b><\/i>329-342.<\/i><\/p>\n

5) <\/strong>Tillman, E.S.; Koscho, M.; Grubbs, R.H.;\u00a0Lewis\u00a0,\u00a0N.S.\u00a0\u00a0 \u201cEnhanced Sensitivity To and Classification of Volatile Organic Acids Using Arrays of Linear Poly(ethyleneimine)-Carbon Black Composite Vapor Detectors.\u201d\u00a0\u00a0Analytical Chemistry\u00a0<\/i>2003,\u00a0<\/b>75<\/i>,\u00a0<\/b>1748-1753.<\/p>\n

4) <\/strong>Tillman, E.S.; Hogen-Esch, T.E \u201cMechanism of Coupling Reactions of Polystyryllithium with Dihalomethanes.\u201d\u00a0\u00a0Journal of Polymer Science, Part A: Polymer Chemistry<\/i>\u00a0\u00a02002<\/b>,\u00a040<\/i>, 1081-1091.<\/p>\n

3) <\/strong>Alberty, K.A;\u00a0Tillman, E.S<\/strong>.; Carlotti, S.; Bradforth, S.; King, K.; Hogen-Esch, T.E.; Parker, D.; Feast, J.W.\u00a0 \u201cCharacterization and Fluorescence of Macrocyclic Polystyrene by Anionic End to End Coupling.\u00a0 Role of Coupling Reagents.\u201d\u00a0Macromolecules <\/i>2002<\/b>,\u00a035<\/i>, 3856-3865.<\/p>\n

2)<\/b> Tillman, E.S.; Nossarev, G.G.; Hogen-Esch, T.E. \u201cReactions of Polstyryllithiums and Model Lithium Carbanions with 9,10-Bis(halomethyl)anthracenes\u201d\u00a0\u00a0Journal of Polymer Science, Part A: Polymer Chemistry<\/i>\u00a02001<\/b>,\u00a039<\/i>, 3121-3129.<\/p>\n

1) <\/strong>Tillman, E.S.; Hogen\u2013Esch, T.E. \u201cSynthesis of Macrocyclic Polystyrene and Macrocyclic Poly(9,9-dimethyl-2-vinylfluorene) Containing a Single Anthracenylidene Group\u201d\u00a0 Macromolecules\u00a0\u00a0<\/i>2001<\/b>,\u00a034<\/i>, 6616-6622.<\/p>\n

Patents\u00a0<\/b>(student co-inventor*)<\/h2>\n

3) US Patent <\/strong>\u201cNovel Methods of Generating Cyclic Polymers \u201d Inventors: Eric S. Tillman<\/strong>, Elizabeth M. Carnicom<\/u>, and Kenneth D. Myers.<\/u> 2016<\/strong>. Patent number: WO2016022766<\/em><\/p>\n

2) US Patent <\/strong>\u201cMethod of Producing Macrocyclic Polymers\u201d Inventors: Eric S. Tillma<\/strong>n and Andrew F. Voter<\/u>. 2013 <\/strong>Patent Number: US2013013275<\/em><\/p>\n

1) US Patent<\/strong>\u00a0“Use of Basic Polymers in Carbon Black Composite Vapor Detectors to Obtain Enhanced Sensitivity and Classification Performance for Volatile Fatty Acids\u201d Patent No. <\/em>US2005150778-A1 Inventors: Nathan S. Lewis, N.S.; Robert H. Grubbs, R.H.;\u00a0Eric S. Tillman<\/strong>, E.S.; Michael E. Koscho.\u00a02005<\/strong><\/p>\n

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Refereed Publications (*indicates student coauthor) From SCU 49)\u00a0 Chong, J. L.*,\u00a0Burch, A. M.*, Otero, D. M.*,\u00a0Tillman, E. S.\u00a0 “Room Temperature Nickel-catalyzed Reductive Coupling of End-brominated Polystyrene Chains” \u00a0Journal of Polymer Science Part A, Polymer Chemistry 2024, 62, 146 – 152.\u00a0 https:\/\/doi.org\/10.1002\/pol.20230620 48)\u00a0 Basler, E. D.*,\u00a0Chong, J. L.*,\u00a0Heath, C. M.*,\u00a0Ching, K. S.*,\u00a0Jennett, S. T.*,\u00a0Tillman, E. S.,\u00a0Nickel-Catalyzed […]<\/p>\n","protected":false},"author":1334,"featured_media":0,"parent":0,"menu_order":3,"comment_status":"closed","ping_status":"closed","template":"","meta":{"qubely_global_settings":"","qubely_interactions":"","kk_blocks_editor_width":"","_kiokenblocks_attr":"","_kiokenblocks_dimensions":"","footnotes":""},"class_list":["post-18","page","type-page","status-publish","hentry"],"post_mailing_queue_ids":[],"_links":{"self":[{"href":"https:\/\/blogs.scu.edu\/etillman\/wp-json\/wp\/v2\/pages\/18","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/blogs.scu.edu\/etillman\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/blogs.scu.edu\/etillman\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/blogs.scu.edu\/etillman\/wp-json\/wp\/v2\/users\/1334"}],"replies":[{"embeddable":true,"href":"https:\/\/blogs.scu.edu\/etillman\/wp-json\/wp\/v2\/comments?post=18"}],"version-history":[{"count":30,"href":"https:\/\/blogs.scu.edu\/etillman\/wp-json\/wp\/v2\/pages\/18\/revisions"}],"predecessor-version":[{"id":428,"href":"https:\/\/blogs.scu.edu\/etillman\/wp-json\/wp\/v2\/pages\/18\/revisions\/428"}],"wp:attachment":[{"href":"https:\/\/blogs.scu.edu\/etillman\/wp-json\/wp\/v2\/media?parent=18"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}