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Refining Archaeological Data Collection and Management

Published online by Cambridge University Press:  27 February 2023

Michael Heilen*
Affiliation:
Statistical Research Inc., Haymarket, VA, USA
Shelby A. Manney
Affiliation:
Arizona Army National Guard, Phoenix, AZ, USA
*
(mheilen@sricrm.com, corresponding author)
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Abstract

Most archaeological investigations in the United States and other countries must comply with preservation laws, especially if they are on government property or supported by government funding. Academic and cultural resource management (CRM) studies have explored various social, temporal, and environmental contexts and produce an ever-increasing volume of archaeological data. More and more data are born digital, and many legacy data are digitized. There is a building effort to synthesize and integrate data at a massive scale and create new data standards and management systems. Taxpayer dollars often fund archaeological studies that are intended, in spirit, to promote historic preservation and provide public benefits. However, the resulting data are difficult to access and interoperationalize, and they are rarely collected and managed with their long-term security, accessibility, and ethical reuse in mind. Momentum is building toward open data and open science as well as Indigenous data sovereignty and governance. The field of archaeology is reaching a critical point where consideration of diverse constituencies, concerns, and requirements is needed to plan data collection and management approaches moving forward. This theme issue focuses on challenges and opportunities in archaeological data collection and management in academic and CRM contexts.

La mayoría de las investigaciones arqueológicas en los Estados Unidos y otros países deben cumplir con las leyes de preservación, si se encuentran en propiedad del gobierno o cuentan con el apoyo de fondos del gobierno. Los estudios académicos y de gestión de recursos culturales (en inglés, CRM) han explorado varios contextos sociales, temporales y ambientales y producen un creciente volumen de datos arqueológicos. Cada vez más datos son de origen digital y muchos datos heredados se digitalizan. Existe un creciente esfuerzo para sintetizar e integrar datos a gran escala y crear nuevos estándares de datos y sistemas de gestión. Los dólares de los contribuyentes a menudo financian estudios arqueológicos cuyo objetivo es, en espíritu, promover la preservación histórica y proporcionar beneficios públicos. Sin embargo, los datos resultantes son difíciles de acceder e más difíciles de poner en práctica y rara vez son recopilados y gestionados tomando en cuenta la seguridad, accesibilidad y reutilización ética de los datos a largo plazo. Un impulso está creciendo para apoyar los datos abiertos y “ciencia pública”, además de reconocer la soberanía de los pueblos indígenas sobre la gobernanza de los datos indígenas. El campo de la arqueología está llegando a un punto crítico donde es necesario considerar diversos grupos, preocupaciones y requisitos para planificar la recopilación de datos y los enfoques de gestión en el futuro. El tema de este número se centra en los desafíos y oportunidades en la recopilación y gestión de datos arqueológicos en contextos académicos y de gestión de recursos culturales.

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Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of Society for American Archaeology

Globally, academic and cultural resource management (CRM) projects produce vast quantities of archaeological data. Most of these data are collected in compliance with preservation laws and regulations. A staggering amount of work has been done in US CRM since the passage of the National Historic Preservation Act of 1966 and the National Environmental Policy Act of 1969, for example (Altschul Reference Altschul2016a; McManamom Reference McManamom and McManamon2018a, Reference McManamom2018b). Most of the money spent on US CRM efforts each year—$1.4 billion in 2020 (SRI Foundation 2020)—is devoted to performing basic compliance in response to individual projects when and where they arise. Despite the enormous scale and predictability of CRM work, there has been a limited effort to refine and operationalize data practices to meet today's evolving management and research needs (Halford Reference Halford, Baldrica, DeBunch and Fowler2019; Schlanger et al. Reference Schlanger, Wilshusen and Roberts2015). Many CRM efforts follow data collection standards and methods that have become stagnant and routinized without assessing their accuracy and reliability (Altschul Reference Altschul2016a; Halford Reference Halford, Baldrica, DeBunch and Fowler2019; Shott Reference Shott and Wandsnider1992). Moreover, many of the resulting data remain hard to locate, access, integrate, and reuse (Atici et al. Reference Atici, Kansa, Lev-Tov and Kansa2013; Faniel and Yakel Reference Faniel, Yakel and Johnston2017; Kansa et al. Reference Kansa, Atici, Kansa and Meadow2019; Kintigh Reference Kintigh2006; Kintigh et al. Reference Kintigh, Altschul, Kinzig, Fredrick Limp, Michener, Sabloff, Hackett, Kohler, Ludäscher and Lynch2015; McManammon Reference McManamom and Smith2018c; Richards et al. Reference Richards, Austin and Hardman2010; Watts Reference Watts2011; York et al. Reference York, Gutmann and Berman2018). As Schlanger and colleagues (Reference Schlanger, Wilshusen and Roberts2015:92) articulate, “We create data in greater detail and greater volume than ever before, yet we do not know what to do with much of it, and have few effective means of sharing it, managing it, analyzing it, or archiving it.”

Projects such as ARIADNE and ARIADNEplus in Europe (https://ariadne-infrastructure.eu/) and Digital Antiquity (https://live-digant.ws.asu.edu/) and Open Context (https://opencontext.org/) in the United States have successfully archived and indexed many archaeological datasets and, in some cases, link datasets and provide tools for data integration. Nevertheless, many archaeological data are not collected either with their future integration and reuse in mind or in consideration of how they will be accessed and governed over the long term. In this journal issue, we envision a future where archaeological data are collected and managed in deliberate, purposeful ways that allow them to be (a) useful throughout the life of a project, (b) accessible and reusable after a project has ended, and (c) governed during and after a project in ways that honor the rights, needs, and requirements of diverse data constituencies and stakeholders. To do this, archaeological data will need to be intentionally modeled, collected, and managed in full anticipation of being accessed, interoperationalized, and reused by multiple constituencies for diverse and sometimes conflicting purposes. In this future, archaeological data will be collected and managed as living data that retain utility beyond the purpose for which they were generated—that is, data that are not only reusable but also “re-useful.”

As federal agencies such as the US Bureau of Land Management transition from “site-centric” to landscape approaches, they need the ability to rapidly integrate and interpret archaeological data from many projects over large areas and across jurisdictions. Synthetic and interdisciplinary research using “big” archaeological data will also require data to be integrated and managed at a scope, scale, and rate consistent with the level at which data are now collected (Altschul Reference Altschul2016b; Doelle et al. Reference Doelle, Barker, Cushman, Heilen, Herhahn and Rieth2016; Halford Reference Halford, Baldrica, DeBunch and Fowler2019; Huggett Reference Huggett2020a). Yet, the bewildering variety of systems that archaeologists use to record and manage data are rarely designed to anticipate other practitioners’ research questions or how future projects or management approaches may reuse data (Kansa and Kansa Reference Kansa and Kansa2021; Pavel Reference Pavel2010). This problem is further complicated because archaeological data collection methods often extract from or destroy nonrenewable resources, rendering data collection from the same context nonrepeatable (Lipe Reference Lipe1974, Reference Lipe, Sebastian and Lipe2009; Pavel Reference Pavel2010, Reference Pavel2012; cf. Roosevelt et al. Reference Roosevelt, Cobb, Moss, Olson and Ünlüsoy2015). There are few opportunities for a do-over in archaeology and few examples of reproducible archaeological research.

Combining archaeological data from multiple projects to address a particular research question or management concern can be exceedingly time consuming and challenging in the current data ecosystem. Many questions may arise concerning how data were collected and recorded, what they represent, and how they can or cannot be successfully standardized, harmonized, leveraged, and reused. Some of these questions will be difficult or impossible to answer. The extra time and effort needed to prepare and validate a combined dataset detract from the amount of time and effort that can be applied to exploring and learning from the dataset. By failing to plan for long-term access, interoperability, and reuse, existing data practices diminish the ability to leverage archaeological data for research and management. Ultimately, this limits what can be learned from archaeological data about history, the environment, and the human experience. By contrast, quickly and confidently locating, accessing, and integrating data from multiple projects can dramatically increase research efficiency (Beagrie and Houghton Reference Beagrie and Houghton2013). Archaeologists need to find ways to exchange the vast amount of effort now required to wrangle data into useable and reliable data products with effort spent instead on interacting with data to gain knowledge and insight.

Refining archaeological data collection and management requires consideration of the entire workflow and data life cycle—and how data are to be governed throughout the data life cycle. Methods and practices implemented in one phase of the data life cycle will impact the outcome of other phases positively and negatively (Kansa and Kansa Reference Kansa and Kansa2022; Yakel et al. Reference Yakel, Faniel and Maiorana2019). Archaeologists and cultural resource management practitioners need to step away from the project-by-project mindset and view their efforts as part of a larger physical and metaphorical landscape of archaeological research and heritage work. Although the project-based, archival focus of the current CRM data ecosystem can provide acceptable management results in isolation, far better research and management outcomes could be achieved if archaeologists conceptualized and worked with data at broader and more inclusive scales. We must transition from thinking of data as a means to accomplish a project goal to thinking of data more holistically as valuable (and often public) assets that can provide extended benefits over the long term for multiple constituencies and purposes. This transition will need to consider heritage values more broadly, collecting data to be interoperable and reusable, and managing data following centralized, standardized, and inclusive methods. Archaeologists need to adopt an ethic of data preservation and extensibility.

The authors in this issue of Advances in Archaeological Practice all have a common theme to think “bigger” about archaeological data and the data life cycle. By bigger, we are referring not only to the scale at which archaeological data can be aggregated but also to how archaeologists transform data into narratives, meanings, and conclusions. Furthermore, archaeologists and cultural resource practitioners must consider how the collection, management, and dissemination of archaeological data impact, help, or imperil living descendant cultures and communities. From various points of view, the authors explore the complexities surrounding the data life cycle. The authors in this issue present examples of approaching archaeological data as living data rather than static siloed data that are collected, analyzed, and utilized for a singular short-term purpose.

This introductory article provides a foundation for the others in this issue by defining archaeological data, overviewing the data life cycle, and identifying some of the legal requirements surrounding their collection and management. We then outline what we see as archaeology's “data problem.” Next, we discuss how articles in this issue address data collection and management challenges. We conclude with a “call to action” for all archaeologists to take concrete, positive steps toward improving archaeological data collection and management methods and practices.

ARCHAEOLOGICAL DATA AND DATA PRACTICES

Perhaps more than ever, archaeologists need to be cognizant of data practices—both their own and their colleagues’—and how those practices affect research, management, and heritage. A preliminary step required for “thinking bigger” about data is for archaeologists to broaden their understanding of data as part of a continuous life cycle. Although definitions vary, the data life cycle refers to the main stages and transformations that data take as they move from the planning of data acquisition to data recording, processing, analysis, interpretation, dissemination, curation, and reuse (Borgman Reference Borgman2019; Faniel et al. Reference Faniel, Austin, Kansa, Kansa, France, Jacobs, Boytner and Yakel2018; Liu Reference Liu, Loudcher, Darmont, Noûs, Desai, Ullman, McClatchey and Toyoma2021; McManamon and Ellison Reference McManamon, Ellison, Lercari, Wendrich, Porter, Burton and Levy2022; Williams and Williams Reference Williams and Williams2019; Yakel et al. Reference Yakel, Faniel and Maiorana2019). Archaeologists should plan for each stage of the data life cycle and consider, throughout this cycle, ethical implications and access.

Archaeological data are diverse and come in many forms. A great deal of archaeological data documents the location, characteristics, disposition, and context of material remains observed during field or laboratory studies. Archaeological data also include ethnoarchaeological studies, historical contexts, administrative topics, legal records, and computational data from analyses, experiments, and simulations (Huggett Reference Huggett2022; Kansa and Kansa Reference Kansa and Kansa2021; Kintigh et al. Reference Kintigh, Spielmann, Brin, Selçuk Candan, Clark and Peeples2018; Marwick and Pilaar Birch Reference Marwick and Pilaar Birch2018). By themselves, archaeological data have no inherent meaning. Data must be processed, structured, and interpreted to derive meaning and context. To effectively share, integrate, and reuse archaeological data, metadata are needed that convey how datasets are structured, standardized, related, and encoded. Paradata are needed to document the methods, limitations, and contexts in which data were collected and analyzed (Atici et al. Reference Atici, Kansa, Lev-Tov and Kansa2013; Börjesson et al. Reference Börjesson, Sköld, Friberg, Löwenborg, Pálsson and Huvila2022; Huggett Reference Huggett2020b; McManamon and Ellison Reference McManamon, Ellison, Lercari, Wendrich, Porter, Burton and Levy2022). Without metadata and paradata, identifying and controlling for bias when integrating and (or) reusing data can be difficult or impossible. Controlling for bias requires transparent documentation of the methods used throughout the data life cycle, standardized data practices, and consideration of whether data collection methods are adequate to meet evolving research and management needs.

ACCOUNTING FOR BIAS IN DATA COLLECTION

Some of the most significant impacts on archaeological data and the data life cycle stem from how data are collected and recorded (Yakel et al. Reference Yakel, Faniel and Maiorana2019). If archaeologists put effort into rendering data more interoperable and reusable, they also need to consider whether the methods used to collect data will be effective for that purpose. Many conceptual, environmental, and methodological factors can bias archaeological data collection, thereby affecting the outcome of all subsequent stages in the data life cycle. For example, artifact identification methods, spacing intervals, lighting, artifact characteristics, density, and surface visibility affect what archaeologists identify and record during a survey. Researchers have studied and modeled the effects of several biases on field research, and many have proposed methods to identify and control for bias (Banning Reference Banning2002; Banning et al. Reference Banning, Hawkins and Stewart2006, Reference Banning, Hawkins and Stewart2011, Reference Banning, Hawkins, Stewart, Hitchings and Edwards2016; Gnaden and Holdaway Reference Gnaden and Holdaway2000; Hawkins et al. Reference Hawkins, Stewart and Banning2003; Heilen and Altschul Reference Heilen and Altschul2013; Plog et al. Reference Plog, Plog and Wait1978; Schiffer et al. Reference Schiffer, Sullivan and Klinger1978; Shott Reference Shott1995; Shott et al. Reference Shott, Tiffany, Doershuk and Titcomb2002; Stewart Reference Stewart2006; Wandsnider and Camilli Reference Wandsnider and Camilli1992). Yet, there has been little interest in accounting for bias in CRM practice and little emphasis on managing the kinds of metadata and paradata needed to control for bias when data are reused.

A significant source of bias stems from uncritical reliance on the site concept. CRM efforts routinely carve archaeological landscapes into arbitrary pockets of time, space, and data—that is, sites. Although sites can serve as convenient units of analysis and management, relying on them as fundamental data collection units can distort the interpretation of the archaeological record (Colwell and Ferguson Reference Colwell and Ferguson2014; Dunnell Reference Dunnell, Rossignol and Wandsnider1992; Ebert Reference Ebert1992; Leckman and Heilen Reference Leckman and Heilen2023; McCoy Reference McCoy2020) as well as frustrate reuse of primary data. Many survey approaches, for example, focus observation primarily on recording high-density scatters and rare artifact types. Wandsnider and Camilli (Reference Wandsnider and Camilli1992:182) point out that “the perception that the archaeological record consists of rare ‘hot spots’ in high artifact density and just a few dispersed artifacts is heavily reinforced by traditional discovery techniques.” Focusing on only one segment of the archaeological record can lead to erroneous interpretations of behavioral patterns and cultural processes and, ultimately, to misapprehension and mismanagement of the archaeological record. In this issue, Leckman and Heilen (Reference Leckman and Heilen2023) present a pedestrian survey method that allows systematic and transparent delineation of sites and site components required for legal compliance and management while simultaneously generating standardized, reusable data that archaeologists can aggregate into cumulative datasets suitable for addressing unanticipated research questions, with or without sites as units of analysis (Heilen and Murrell Reference Heilen and Murrell2015; Miller et al. Reference Miller, Kenmotsu and Landreth2009; O'Leary et al. Reference O'Leary, Kludt, Church and Mauldin1997; Seaman et al. Reference Seaman, Doleman and Chapman1988). They show how the method allows archaeologists to aggregate relatively fine-grained primary data from multiple survey projects to infer landscape-level patterns and processes, such as identifying precontact foot trails and mobility patterns across their area of study (Miller et al. Reference Miller, Graves, Ernst, Swanson, Rocek and Kenmotsu2018).

Another form of bias in data collection is that archaeologists often base survey results on a single snapshot in time. When another set of archaeologists resurveys an area, they often assume that the latest recording episode is the most authoritative and accurate (Heilen et al. Reference Heilen, Nagle and Altschul2008). Field experiments have shown that surface archaeology is not static, however. What is exposed and visible to archaeologists in the field varies through time due to disturbance, ongoing and episodic earth surface processes, and changes in field conditions, such as those following rain, plowing, vegetation change, wildfire, or erosion. Moreover, dynamic geomorphic processes and ground conditions differentially influence the observable distribution of artifacts and features across the landscape. For this reason, repeat observation of geomorphic landscape elements at different points in time can be essential to accurately and reliably interpreting a surface assemblage (Holdaway and Fanning Reference Holdaway and Fanning2008; Shott Reference Shott1995; Shott et al. Reference Shott, Tiffany, Doershuk and Titcomb2002). In this issue, Douglass, Holdaway, and Wandsnider (Reference Douglass, Wandsnider and Holdaway2023) consider what archaeologists can learn when they incorporate repeat observation and a geomorphological landscape perspective into field surveys. With revised field methods that account for the dynamic nature of archaeological landscapes, archaeologists can arrive at entirely new interpretations of culture history and land use. Without revised methods, they argue, the archaeological sample preserved for future generations is likely to be biased and unrepresentative (see, for example, Lipe Reference Lipe1974, Reference Lipe, Sebastian and Lipe2009).

Data collection biases can also limit what archaeologists and land managers learn through consultation with stakeholders and how they apply that information to research and management. Most consultations are project specific and focus only on sites that may be affected by a project (Anschuetz and Dongoske Reference Anschuetz and Dongoske2017; Ferguson Reference Ferguson, Sebastian and Lipe2009; Watkins and Ferguson Reference Watkins, Ferguson, Maschner and Chippindale2005). Landscape elements and characteristics that may be of equal or greater interest to stakeholders—such as important plants, water resources, habitats, viewsheds, soundscapes, and landmarks—are often ignored or underappreciated (Colwell and Ferguson Reference Colwell and Ferguson2014; Ferguson et al. Reference Ferguson, Koyiyumptewa and Hopkins2015; Heilen and Altschul Reference Heilen and Altschul2019; Stoffle et al. Reference Stoffle, Arnold, Van Vlack, O'Meara and Savage2009; Toupal et al. Reference Toupal, Nives Zedeño, Stoffle and Barabe2001; Zedeño et al. Reference Zedeño, Austin and Stoffle1997). The way some archaeological investigations are conducted has the effect of omitting, ignoring, or diminishing Indigenous perspectives while simultaneously colonizing, appropriating, and disrupting Indigenous heritage and lifeways (Dongoske and Anschuetz Reference Dongoske and Anschuetz2021).

Sarah Schlanger (Reference Schlanger2023) addresses archaeology's data problem in this issue from a land management perspective that broadly considers the diverse and sometimes conflicting values that Indigenous communities and other stakeholders place in cultural resources and landscapes (Lipe Reference Lipe, Sebastian and Lipe2009; McManamon et al. Reference McManamon, Doershuk, Lipe, McCulloch, Polglase, Schlanger, Sebastian and Sullivan2016). Schlanger argues that managers must consider how different constituencies value a landscape and its characteristics, and how they prefer to experience those values. She recommends that data collection methods for managing culturally significant landscapes should include inventorying and monitoring landscape characteristics integral to stakeholders’ experience of place, instead of placing emphasis primarily on the documentation and avoidance of individual archaeological sites and other sensitive resources.

These are a few ways to refine data collection methods to produce more meaningful and reusable archaeological data, but they are by no means the only or the right way. The point of these articles is that if we are going to plan for a more visionary future that makes better and more holistic and ethical use of archaeological data, we must start with consideration of how the data are collected and whether those data will serve archaeology and the public well—both now and in the future. Revised collection methods will have to address biases, allow for interoperability, consider descendant community concerns, and anticipate refinements in subsequent steps of the data life cycle.

DATA MANAGEMENT

After data collection, the data life cycle usually ends prematurely, in “data death,” with the completion of a project. For archaeologists to think bigger, data must be planned, integrated, and managed more effectively at broader scales. The only way archaeology can prepare for future access and reusability of archaeological data is by managing its data assets at every stage of the data life cycle (Niven Reference Niven2011). A data management plan that addresses the entire data life cycle is now considered essential for every archaeological project (Baker and Duerr Reference Baker, Duerr and Johnston2017; Kansa and Kansa Reference Kansa and Kansa2021; Kansa et al. Reference Kansa, Atici, Kansa and Meadow2019). However, academic researchers, land managers, and CRM contractors continue to manage a great deal of archaeological data without clear and detailed data management plans and without confronting difficult questions regarding how to care for archaeological data over the long term (McManamon and Ellison Reference McManamon, Ellison, Lercari, Wendrich, Porter, Burton and Levy2022; McManamon et al. Reference McManamon, Kintigh, Ellison and Brin2017; Wright and Richards Reference Wright and Richards2018). The data life cycle must not end with a publication or contract completion. Rather, archaeological data need to live on so that they are permanently curated and accessible, and so that they can be reused for research and management needs different from the immediate purpose for which they were initially generated.

Extensive efforts have been undertaken in Europe to improve the management and accessibility of archaeological data by integrating digital repositories and datasets across Europe with the ARIADNE and ARIADNEplus projects. Digital Antiquity and Open Context have been fulfilling similar archiving and cataloging functions in the United States. The vast majority of archaeological data have yet to find their way into a digital archive, let alone in ways that support their interoperability and reuse.

In the United States, many states and federal agencies (e.g., the Army Corps of Engineers, Bureau of Land Management, Forest Service, National Park Service) now have digital CRM databases containing data on thousands of projects and sites (Halford and Ables Reference Halford and Ables2023; Wilshusen et al. Reference Wilshusen, Heilen, Catts, de Dufour and Jones2016). Most store derivative, summary information about archaeological sites and project areas—not the primary data. The data within and between databases also varies in quality, reliability, consistency, standardization, and completeness. In many cases, access to precise locational data is restricted, diminishing the saliency and reusability of archaeological data for many avenues of research (Ortman and Altschul Reference Ortman and Altschul2023; Robinson et al. Reference Robinson, Nicholson and Kelly2019). Many primary data are difficult or impossible to access, buried in site cards and reports, or even stored on a personal computer, often without adequate metadata and paradata. As a result, the conclusions of an archaeological project often “cannot be immediately followed or traced back to primary evidence” (Pavel Reference Pavel2010:6). Even when data are available, many data continue to be modeled and managed on a project-by-project level, primarily for archival rather than analytical purposes, and following diverse data structures and formats, minimal standardization, and limited adherence to standard ontologies and typologies (Kansa and Kansa Reference Kansa and Kansa2021; Kintigh et al. Reference Kintigh, Spielmann, Brin, Selçuk Candan, Clark and Peeples2018; Marwick Reference Marwick2017).

Many archaeologists may not realize that in the United States, by regulation, archaeological data collected with federal funds or on federal property must be appropriately stored, made accessible to potential users, and managed in perpetuity (Cultural Heritage Partners 2012). As Clarke (Reference Clarke2015:322) advises, “Recent changes in academia and federal funding have made it so that there is no longer a choice, and scholars are now legally responsible for preservation of research data.” Multiple federal regulations and statutes have authorized curation and access to data, records, reports, samples, physical artifacts, and other remains. These include the American Antiquities Act of 1906, the Archaeological Resources Protection Act of 1979 (as amended), the National Historic Preservation Act of 1966 (as amended), Federal Regulation 36 CFR 79 (Curation of Federally Owned and Administered Archeological Collections), public records laws, and National Archives regulations.

The state of archaeological data management in the United States has created significant barriers to effectively managing the archaeological record by lacking shared data standards and limiting access to information by those who need it (Halford Reference Halford, Baldrica, DeBunch and Fowler2019). The US Bureau of Land Management has taken steps to remove some of these barriers within its agency by creating the National Cultural Resource Information Management System (NCRIMS), as presented in this issue by Halford and Ables (Reference Halford and Ables2023). NCRIMS uses complex Python scripts unique to each contributing database to annually extract, translate, and upload data into the system. Although the system allows authorized users to rapidly assess cultural resource distributions over large areas following a landscape approach to managing public lands (Altschul Reference Altschul2016b; Clement et al. Reference Clement, Belin, Bean, Boling and Lyons2014), it also begs the question of why such a system is necessary. Are archaeological contexts and research questions in individual states so different from each other that they must be maintained following separate data standards and formats? Is it possible to develop a shared standard that facilitates the integration of most archaeological data while still allowing room for experimentation and refinement?

Archaeological data are increasingly born digital and could be originated and maintained within integrated data management systems following common standards (Niven Reference Niven2011). As Sarah Kansa and colleagues (Reference Kansa, Atici, Kansa and Meadow2019:2) note, when “multiple kinds of data can be efficiently and meaningfully aggregated, it will become possible to discern and explore new spatial and temporal patterns using analytically rigorous methods.” Archaeology can contribute uniquely to a deep-time perspective on contemporary issues with significant public policy implications, such as social inequality, migration, climate change, wildfire, violence, urbanization, disease, and health (Altschul Reference Altschul2016a; Altschul et al. Reference Altschul, Kintigh, Klein, Doelle, Hays-Gilpin, Herr and Kohler2017, Reference Altschul, Kintigh, Klein, Doelle, Hays-Gilpin, Herr and Kohler2018; Kintigh et al. Reference Kintigh, Altschul, Beaudry, Drennan, Kinzig, Kohler and Fredrick Limp2014; Ortman Reference Ortman2019; Ortman et al. Reference Ortman, Smith, Lobo and Bettencourt2020). Yet, few steps have been taken to realize this capability (Arbuckle et al. Reference Arbuckle, Kansa, Kansa, Orton, Çakırlar, Gourichon and Atici2014; Austin Reference Austin2014; Benden and Taft Reference Benden and Taft2019; Richards Reference Richards2017; Schlanger et al. Reference Schlanger, Wilshusen and Roberts2015). One solution is adhering to the open data and open science principles (Kansa Reference Kansa2010, Reference Kansa2012, Reference Kansa2015; Marwick et al. Reference Marwick, d'Alpoim Guedes, Barton, Bates, Baxter, Bevan and Bollwerk2017).

Open Data and Open Science

The “open” concept refers to making data, information, and knowledge maximally interoperable and freely accessible in open formats to anyone for any purpose, with no institutional barriers to their access. Open data are maintained using clear, unambiguous terms that are understandable by all; fully described to allow users to understand the data's strengths, weaknesses, and limitations; and released as early as possible to allow time for data review and refinement. Crucially, open “data will be in their original, unmodified form and at the finest level of granularity available” (Moore and Richards Reference Moore, Richards, Wilson and Edwards2015; UK Government Cabinet Office 2013: Principle 2 [https://www.gov.uk/government/publications/open-data-charter/g8-open-data-charter-and-technical-annex]; see also Kansa Reference Kansa2012). Proponents of open data in archaeology anticipate that improved access to primary archaeological data will provide greater accountability, transparency, and repeatability in archaeological research. This change could, in turn, revitalize archaeological research, lead to new insights and creative reuse, and improve disciplinary interaction (Kansa Reference Kansa2012; Marwick et al. Reference Marwick, d'Alpoim Guedes, Barton, Bates, Baxter, Bevan and Bollwerk2017; Moore and Richards Reference Moore, Richards, Wilson and Edwards2015).

For archaeological data to be more open, data products must be findable, accessible, interoperable, and reusable (FAIR; Wilkinson et al. Reference Wilkinson, Dumontier, Aalbersberg, Appleton, Axton, Baak and Blomberg2016, Reference Wilkinson, Dumontier, Sansone, da Silva Santos, Prieto, Batista and McQuilton2019). In this issue, Nicholson, Kansa, Gupta, and Fernandez (Reference Nicholson, Kansa, Gupta and Fernandez2023) emphasize that FAIR principles apply to a wide range of primary and derivative data products. However, their application in archaeology remains minimal for a variety of reasons. There are currently few incentives for individual researchers or contracting firms to share data, and there are concerns that data sharing will expose errors or preempt publication, fail to credit data creators, and encourage misappropriation or mishandling of sensitive data by those who gain access (Atici et al. Reference Atici, Kansa, Lev-Tov and Kansa2013; Marwick Reference Marwick2017; Marwick and Pilaar Birch Reference Marwick and Pilaar Birch2018; Moore and Richards Reference Moore, Richards, Wilson and Edwards2015). Eric Kansa (Reference Kansa2012:507) warns that withholding archaeological data undermines the integrity of the archaeological record and can amount to the “personal, self-aggrandizing appropriation of cultural heritage.” By contrast, sharing primary data accompanied by adequate metadata and paradata can support reproducibility of research results (Marwick Reference Marwick2017). It can also “foster adherence to more consistent and comparable approaches to the recording and reuse of data” (Kansa et al. Reference Kansa, Atici, Kansa and Meadow2019:2). For shared data to be usable, standard vocabularies and “better methods to model, create, clean, and document” are needed, along with reward systems that encourage good practice in generating and sharing reusable data (Beebe Reference Beebe2017; Heckman et al. Reference Heckman, Heilen and Leckman2020; Kansa et al. Reference Kansa, Atici, Kansa and Meadow2019:2).

A concern is that open data initiatives place inadequate attention on “the impacts of colonialism on the practice of science and have overlooked the interests and rights of Indigenous peoples when it comes to data ownership, sharing, and knowledge creation” (Gupta et al. Reference Gupta, Blair and Nicholas2020:539). Applying FAIR principles to archaeological data requires that archaeologists account for the colonial roots of archaeological research, fundamental differences between scientific and Indigenous epistemologies, and the sovereign rights of Indigenous Peoples to control their heritage, including controlling any data related to that heritage (Dongoske and Anschuetz Reference Dongoske and Anschuetz2021; Ross et al. Reference Ross, Sherman, Snodgrass, Delcore and Sherman2011). Similar concerns are emerging among other stakeholder groups, such as African American and Asian American communities seeking greater control over and access to heritage. Consequently, although there is a growing interest in making archaeological data FAIR, there is a concomitant need to decide how archaeological and other heritage data should be governed.

Data Governance

Data governance frameworks require the archaeological community to address numerous questions about how data can be accessed, shared, processed, documented, and controlled; what permissions and permission systems are needed; and who has the right to decide on data practices. Indigenous data governance is an emerging topic discussed in this issue by Gupta, Martindale, Supernant, Huddlestan, and Elvidge (Reference Gupta, Martindale, Supernant and Elvidge2023) that affects all aspects of the data life cycle. Indigenous data are data of any form that “impact Indigenous Peoples, nations, and communities at the collective and individual levels,” including data on their environment, history, and heritage (Carroll et al. Reference Carroll, Herczog, Hudson, Russell and Stall2021:1; Kukutai and Taylor Reference Kukutai and Taylor2016). The United Nations Declaration on the Rights of Indigenous Peoples reaffirms that they have a right to access, enjoy, practice, revitalize, and preserve their heritage, including their right to control Indigenous data. Yet, many data are not even findable or accessible to the communities that might claim them as part of their heritage and have instead “been kept from Indigenous communities, often inadvertently” (Nicholas and Bannister Reference Nicholas and Bannister2004:339). Archaeologists, archaeological institutions, cultural resource firms, and government entities control most archaeological data in the United States, Canada, and other countries. Advocates of Indigenous data governance insist that Indigenous communities have a sovereign right to control Indigenous data and govern how they are collected, accessed, used, and disseminated (van Schilfgaarde Reference van Schilfgaarde2020). As Nicholas and Bannister (Reference Nicholas and Bannister2004:339) explain, “Whoever owns (or controls records of) the past also owns or otherwise shapes the future of that past.”

These concerns have led to the development of the CARE Principles for Indigenous Data Governance (https://www.gida-global.org/care; see Gupta et al. Reference Gupta, Martindale, Supernant and Elvidge2023, this issue). First drafted in 2018, the CARE Principles promote collective benefit, authority to control, respect, and ethics in practices involving Indigenous data. Establishing Indigenous data sovereignty through data governance frameworks would reposition Indigenous Peoples from being subjects of inquiry to being active participants and leaders in heritage research, policy, and management (Carroll et al. Reference Carroll, Herczog, Hudson, Russell and Stall2021). To some archaeologists, Indigenous data governance frameworks may appear to divest archaeologists of control over how archaeologists collect, use, and share data. On the other hand, such frameworks also provide an opportunity to decolonize archaeology and redress past wrongs while fostering greater collaboration with Indigenous Peoples and greater respect for Indigenous rights and interests. Adherence to Indigenous data governance frameworks could also help archaeology achieve greater relevance by (a) refining data practices to better support the protection of Indigenous rights, interests, and heritage; and (b) enriching research and policy with knowledge and perspectives that Indigenous communities choose to share (Atalay Reference Atalay2012, Reference Atalay2020; Laluk et al. Reference Laluk, Montgomery, Tsosie, McCleave, Miron, Carroll and Aguilar2022; Larson et al. Reference Larson Evan, Kipfmueller and Johnson2020; Ogar et al. Reference Ogar, Pecl and Mustonen2020). In the future, data governance frameworks will likely be viewed as essential tools for guiding archaeological data practices and the data life cycle.

RECONCEPTUALIZING ARCHAEOLOGICAL DATA AS LIVING DATA

The life cycle of archaeological data often results in the data being put to rest and largely unavailable for reuse, even though US regulations—and those of many other nations—require archaeological data to be preserved based on regulated data access and storage standards and in a manner that makes data both accessible and reusable in the future (Kintigh Reference Kintigh2018). Archaeological data need to be reconceptualized as living data that retain utility beyond the immediate purpose for which they were generated. Ideally, academic archaeology and CRM would benefit from adopting a more unified set of methods and standards with baseline assumptions that allow for more robust interoperability and comparison among datasets while simultaneously providing room for experimentation. CRM needs to shift from thinking of data as an administrative record of individual projects, sites, and deposits to thinking of data as part of a living, integrated digital ecosystem that includes the following:

  • Published ontologies and data dictionaries

  • Collaborative tools and methods for creating ontologies and normalizing and harmonizing data

  • Tools and methods for uploading, citing, cross-referencing, and linking datasets

  • Permission systems and data tags for controlling access and use of culturally sensitive or restricted data

  • Standards, templates, and guidelines for recording the metadata needed to locate, display, and analyze the data—as well as the paradata needed to understand the methods, processes, and quality associated with them

  • Centralized systems for ethically ingesting, managing, and disseminating archaeological data at scales consistent with the scale at which data are collected

A final stage in the data life cycle is data reuse. In this issue, Ortman and Altschul (Reference Ortman and Altschul2023) confront the problem that there currently is no system in the United States or elsewhere for integrating and digesting archaeological data at the scale and scope in which archaeologists collect data, let alone in ways that make archaeological data directly useful for the social science research community and other disciplines. In other social science disciplines—such as demography, economy, geography, and sociology—a well-staffed government agency such as the US Census Bureau is responsible for translating raw data into standard data products for regional- and national-scale research. Although researchers and organizations have made significant advances in integrating archaeological data, they tend to follow one of three strategies: (1) aggregating data of a restricted type, such as radiocarbon dates (Bird et al. Reference Bird, Miranda, Linden, Robinson, Kyle Bocinsky, Nicholson and Capriles2022; Kelly et al. Reference Kelly, Mackie, Robinson, Meyer, Berry, Boulanger and Codding2022) or tree-ring dates (Robinson and Cameron Reference Robinson and Cameron1991); (2) creating digital archives or indexes for finding and accessing archaeological datasets (Kansa Reference Kansa2010; Kintigh et al. Reference Kintigh, Spielmann, Brin, Selçuk Candan, Clark and Peeples2018; Richards Reference Richards2017; Sheehan Reference Sheehan2015; Wells et al. Reference Wells, Kansa, Kansa, Yerka, Anderson, Bissett, Myers and Carl DeMuth2014); or (3) creating integrated research databases for a particular region or research problem (Hegmon et al. Reference Hegmon, Russell, Baller, Peeples and Striker2021; Mills et al. Reference Mills, Ram, Clark, Ortman and Peeples2020; Neusius et al. Reference Neusius, Styles, Peres, Walker, Crothers, Smith and Colburn2019; Pluckhahn and Wallis Reference Pluckhahn and Wallis2017). Ortman and Altschul (Reference Ortman and Altschul2023) present a vision to develop a national archaeological data service for the United States that would be built around the most common and consistent data that archaeologists record—spatial data—with built-in mechanisms for protecting the sensitivity of those data and governing how they may be accessed and used (see also McKeague et al. Reference McKeague, Corns, Larsson, Moreau, Posluschny, Van Daele and Evans2020).

CONCLUSIONS

This journal issue is ultimately about refining data practices to improve archaeological data's durability, utility, and ethical reuse. In effecting change in practice, archaeologists must recognize that different incentives exist for different data constituencies, such as federal CRM programs, CRM contractors, academic archaeologists, Indigenous communities, and other disciplines. Despite the substantial investment of government time and expense in the industry, there are few incentives within CRM to experiment with new methods or synthesize data across many projects unless required by a project. Refining archaeological data practices within CRM and for many academic projects may ultimately require implementing data management plans, and practices that (a) adhere to demonstrably effective, ethical, and sustainable data standards and systems; and (b) provide for long-term data access, interoperability, and reuse.

A comparative framework for assessing the costs and benefits of archaeological data collection and management methods is needed to determine which methods will be the most effective and worthy of investment. Archaeologists should consider the entire workflow when refining methods, including the human and digital workflows involved in generating, managing, integrating, analyzing, transforming, curating, and sharing data. Moreover, Indigenous rights and perspectives should be considered, along with the values placed on cultural resources by different constituencies and user groups. Education in digital literacy and ethics, as well as behavior change, are needed to realize change in archaeological data practices. In collaboration with other stakeholders, archaeologists must decide which data are critical to collect and how they should be standardized, encoded, related, and made available to researchers, stakeholders, and the public. What makes these data useful, and to which constituencies are they relevant? How will they be controlled and used now and in the future?

Refining data collection and management practices across the data life cycle will take time, behavioral change, disciplinary “buy-in,” and systemic reform. Multiple tensions will need to be resolved, including deciding on the purposes and goals of archaeological data and data practices, and the degree to which data access and use should be open or restricted. A perfect system with all its parts seamlessly integrated and deconflicted will not emerge spontaneously in whole cloth. Even so, it is time that archaeologists evaluate how their data practices affect different components of the data life cycle and begin collecting and considering data for this more visionary future.

Acknowledgments

We would like to thank the authors of the articles in this issue for their insightful and visionary contributions and for their persistence and dedication in conceptualizing and advocating for refinements in archaeological data collection and management. This article and many other articles in this issue are based on an organized symposium, sponsored by the Arizona Army National Guard, that was held virtually in April 2021 in the midst of a global pandemic during the 86th Annual Meeting of the Society for American Archaeology. We are grateful to all the symposium participants for their contributions to the topics discussed in this issue, including authors who were unable to participate here. We greatly appreciate the many colleagues who peer-reviewed articles in this issue. No permits were required for the work described here.

Funding Statement

We would like to thank the Arizona Army National Guard for its generous support—in the form of staff time, resources, and funding—in helping this special issue come to fruition and in providing funds to ensure that the entire issue could be published Open Access.

Data Availability Statement

No original data were used in this article.

Competing Interests

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this article.

References

REFERENCES CITED

Altschul, Jeffrey H. 2016a. The Role of Synthesis in American Archaeology and Cultural Resource Management as Seen through an Arizona Lens. Journal of Arizona Archaeology 4(1):6881.Google Scholar
Altschul, Jeffrey H. 2016b. The Society for American Archaeology's Task Forces on Landscape Policy Issues. Advances in Archaeological Practice 4(2):102105.CrossRefGoogle Scholar
Altschul, Jeffrey H., Kintigh, Keith W., Klein, Terry H., Doelle, William H., Hays-Gilpin, Kelley A., Herr, Sarah A., Kohler, Timothy A., et al. 2017. Fostering Synthesis in Archaeology to Advance Science and Benefit Society. PNAS 114(42):1099911002.CrossRefGoogle ScholarPubMed
Altschul, Jeffrey H., Kintigh, Keith W., Klein, Terry H., Doelle, William H., Hays-Gilpin, Kelley A., Herr, Sarah A., Kohler, Timothy A., et al. 2018. Fostering Collaborative Synthetic Research in Archaeology. Advances in Archaeological Practice 6(1):1929.CrossRefGoogle Scholar
Anschuetz, Kurt F., and Dongoske, Kurt E.. 2017. Hadiya:Wa: Hearing What Traditional Pueblo Cultural Advisors Talk About. Paper presented at the 82nd Annual Meeting of the Society for American Archaeology, Vancouver.Google Scholar
Arbuckle, Benjamin S., Kansa, Sarah Whitcher, Kansa, Eric, Orton, David, Çakırlar, Canan, Gourichon, Lionel, Atici, Levent, et al. 2014. Data Sharing Reveals Complexity in the Westward Spread of Domestic Animals across Neolithic Turkey. PLoS ONE 9(6):e99845. https://doi.org/10.1371/journal.pone.0099845.CrossRefGoogle ScholarPubMed
Atalay, Sonya. 2012. Community-Based Archaeology: Research with, by, and for Indigenous and Local Communities. University of California Press, Berkeley.Google Scholar
Atalay, Sonya. 2020. Indigenous Science for a World in Crisis. Public Archaeology 19(1–4):3752. https://doi.org/10.1080/14655187.2020.1781492.CrossRefGoogle Scholar
Atici, Levent, Kansa, Sarah, Lev-Tov, Justin, and Kansa, Eric. 2013. Other People's Data: A Demonstration of the Imperative of Publishing Primary Data. Journal of Archaeological Method and Theory 20:663681.CrossRefGoogle Scholar
Austin, Anne. 2014. Mobilizing Archaeologists: Increasing the Quantity and Quality of Data Collected in the Field with Mobile Technology. Advances in Archaeological Practice 2(1):1323.CrossRefGoogle Scholar
Baker, Karen S., and Duerr, Ruth E.. 2017. Research and the Changing Nature of Data Repositories. In Curating Research Data, Volume One: Practical Strategies for Your Digital Repository, edited by Johnston, Lisa R., pp. 3359. Association of College and Research Libraries, Chicago.Google Scholar
Banning, Edward B. 2002. Archaeological Survey. Kluwer Academic/Plenum, New York.CrossRefGoogle Scholar
Banning, Edward B., Hawkins, Alicia L., and Stewart, Sarah T.. 2006. Detection Functions for Archaeological Survey. American Antiquity 71(4):723742.CrossRefGoogle Scholar
Banning, Edward B., Hawkins, Alicia L., and Stewart, Sarah T.. 2011. Sweep Widths and Detection of Artifacts in Archaeological Survey. Journal of Archaeological Science 38(12):34473458. https://doi.org/10.1016/j.jas.2011.08.007.CrossRefGoogle Scholar
Banning, Edward B., Hawkins, Alicia L., Stewart, Sarah T., Hitchings, Philip, and Edwards, Steven. 2016. Quality Assurance in Archaeological Survey. Journal of Archaeological Method and Theory 24:466488. https://doi.org/10.1007/s10816-016-9274-2.CrossRefGoogle ScholarPubMed
Beagrie, Neil, and Houghton, John. 2013. The Value and Impact of the Archaeology Data Service: A Study and Methods for Enhancing Sustainability. Charles Beagrie, Salisbury, United Kingdom.Google Scholar
Beebe, Caroline. 2017. Standard Descriptive Vocabulary and Archaeology Digital Data Collection. Advances in Archaeological Practice 5(3):250264.CrossRefGoogle Scholar
Benden, Danielle M., and Taft, Mara C.. 2019. A Long View of Archaeological Collections Care, Preservation, and Management. Advances in Archaeological Practice 7(3):217223.CrossRefGoogle Scholar
Bird, Darcy, Miranda, Lux, Linden, Marc Vander, Robinson, Erick, Kyle Bocinsky, R., Nicholson, Chris, Capriles, José M., et al. 2022. p3k14c, A Synthetic Global Database of Archaeological Radiocarbon Dates. Scientific Data 9:27. https://doi.org/10.1038/s41597-022-01118-7.CrossRefGoogle ScholarPubMed
Borgman, Christine L. 2019. The Lives and After Lives of Data. Harvard Data Science Review 1(1). https://doi.org/10.1162/99608f92.9a36bdb6.Google Scholar
Börjesson, Lisa, Sköld, Olle, Friberg, Zanna, Löwenborg, Daniel, Pálsson, Gísli, and Huvila, Isto. 2022. Re-Purposing Excavation Database Content as Paradata: An Explorative Analysis of Paradata Identification Challenges and Opportunities. KULA 6(3):118. https://doi.org/10.18357/kula.221.CrossRefGoogle Scholar
Carroll, Stephanie Russo, Herczog, Edit, Hudson, Maui, Russell, Keith, and Stall, Shelley. 2021. Operationalizing the CARE and FAIR Principles for Indigenous Data Futures. Scientific Data 8:108. https://doi.org/10.1038/s41597-021-00892-0.CrossRefGoogle ScholarPubMed
Clarke, Mary. 2015. The Digital Dilemma: Preservation and the Digital Archaeological Record. Advances in Archaeological Practice 3(4):313330.CrossRefGoogle Scholar
Clement, Joel P., Belin, Alletta d'A., Bean, Michael J., Boling, Ted A., and Lyons, James R.. 2014. A Strategy for Improving the Mitigation Policies and Practices of the Department of the Interior: A Report to the Secretary of the Interior from the Energy and Climate Change Task Force. Department of the Interior, Washington, DC.Google Scholar
Colwell, Chip and Ferguson, T. J.. 2014. The Snow-Capped Mountain and the Uranium Mine: Zuni Heritage and the Landscape Scale in Cultural Resource Management. Advances in Archaeological Practice 2(4):234251.CrossRefGoogle Scholar
Cultural Heritage Partners. 2012. Legal Analysis of Federal Requirements for Curation of Digital Archaeological Documents and Data. Report submitted to Office of General Counsel, Arizona State University, Tempe. Electronic document, https://www.tdar.org/wp-content/uploads/2013/01/CHP-Legal-Analysis.pdf, accessed January 30, 2023.Google Scholar
Doelle, William H., Barker, Pat, Cushman, David, Heilen, Michael, Herhahn, Cynthia, and Rieth, Christina. 2016. Incorporating Archaeological Resources in Landscape-Level Planning and Management. Advances in Archaeological Practice 4(2):118131.CrossRefGoogle Scholar
Dongoske, Kurt, and Anschuetz, Kurt. 2021. Cultural Resource Management, Archaeological Collections, and Ethical Issues Associated with Representations of Indigenous Time, Space, Materiality and Historicity. Paper presented at the 86th Annual Meeting of the Society for American Archaeology, online.Google Scholar
Douglass, Matthew J., Wandsnider, Luann, and Holdaway, Simon J.. 2023. Surface Artifact Scatters, Data Collection, and Significance: Case Studies from Australia and the United States. Advances in Archaeological Practice 11(1):2941.CrossRefGoogle Scholar
Dunnell, Robert C. 1992. The Notion Site. In Space, Time, and Archaeological Landscapes, edited by Rossignol, Jacqueline and Wandsnider, LuAnn, pp. 2141. Plenum Press, New York.CrossRefGoogle Scholar
Ebert, James I. 1992. Distributional Archaeology. University of Utah Press, Salt Lake City.Google Scholar
Faniel, Ixchel, Austin, Anne, Kansa, Eric, Kansa, Sarah, France, Phoebe, Jacobs, Jennifer, Boytner, Ran, and Yakel, Elizabeth. 2018. Beyond the Archive: Bridging Data Creation and Reuse in Archaeology. Advances in Archaeological Practice 6(2):105116.CrossRefGoogle Scholar
Faniel, Ixchel M., and Yakel, Elizabeth. 2017. Practices Do Not Make Perfect: Disciplinary Data Sharing and Reuse Practices and Their Implications for Repository Data Curation. In Curating Research Data, Volume One: Practical Strategies for Your Digital Repository, edited by Johnston, Lisa R., pp. 103126. Association of College and Research Libraries, Chicago.Google Scholar
Ferguson, T. J. 2009. Improving the Quality of Archaeology in the United States through Consultation and Collaboration with Native Americans and Descendant Communities. In Archaeology and Cultural Resource Management: Visions for the Future, edited by Sebastian, Lynne and Lipe, William D., pp. 169194. School for Advanced Research, Santa Fe, New Mexico.Google Scholar
Ferguson, T. J., Koyiyumptewa, Stewart B., and Hopkins, Maren P.. 2015. Co-Creation of Knowledge by the Hopi Tribe and Archaeologists. Advances in Archaeological Practice 3(3):249262.CrossRefGoogle Scholar
Gnaden, Denis, and Holdaway, Simon. 2000. Understanding Observer Variations When Recording Stone Artifacts. American Antiquity 65(4):739748.CrossRefGoogle Scholar
Gupta, Neha, Blair, Sue, and Nicholas, Ramona. 2020. What We See, What We Don't See: Data Governance, Archaeological Spatial Databases and the Rights of Indigenous Peoples in an Age of Big Data. Journal of Field Archaeology 45(S1):S39S50.CrossRefGoogle Scholar
Gupta, Neha, Martindale, Andrew, Supernant, Kisha, and Elvidge, Michael. 2023. The CARE Principles and the Reuse, Sharing, and Curation of Indigenous Data in Canadian Archaeology. Advances in Archaeological Practice 11(1):7689.CrossRefGoogle Scholar
Halford, F. Kirk. 2019. The Past and Future of CRM under the Guise of Section 106. In Cultural Resource Management in the Great Basin 1986–2016, edited by Baldrica, Alice M., DeBunch, Patricia A., and Fowler, Don D., pp. 1621. University of Utah Press, Salt Lake City.Google Scholar
Halford, F. Kirk, and Ables, Dayna M.. 2023. The National Cultural Resources Information Management System (NCRIMS): New Horizons for Cultural Resources Data Management and Analyses. Advances in Archaeological Practice 11(1):5262.CrossRefGoogle Scholar
Hawkins, Alicia L., Stewart, Sarah T., and Banning, Edward B.. 2003. Interobserver Bias in Enumerated Data from Archaeological Survey. Journal of Archaeological Science 30:15031512.CrossRefGoogle Scholar
Heckman, Robert A., Heilen, Michael, and Leckman, Phillip O.. 2020. The Potential Role of Cultural Resource Data Collection and Management Systems in Synthetic Research. Paper presented at the 17th Biennial Conference of the Southwest Symposium, Tempe, Arizona.Google Scholar
Hegmon, Michelle, Russell, Will G., Baller, Kendall, Peeples, Matthew A., and Striker, Sarah. 2021. The Social Significance of Mimbres Painted Pottery in the U.S. Southwest. American Antiquity 86(1):2342.CrossRefGoogle Scholar
Heilen, Michael, and Altschul, Jeffrey H.. 2013. The Accuracy and Adequacy of In-Field Artifact Analysis: An Experimental Test at Two Archaeological Sites in the Western United States. Advances in Archaeological Practice 1(2):121138.CrossRefGoogle Scholar
Heilen, Michael, and Altschul, Jeffrey H.. 2019. Connecting the Dots: Integrating Cultural and Natural Resource Management in the United States. Ex Novo 4:3151.CrossRefGoogle Scholar
Heilen, Michael P., and Murrell, Monica. 2015. Assessment of Site Recording and Eligibility Testing Methods at Four Sites in the Permian Basin, Southeastern New Mexico. Technical Report 15–68. Statistical Research, Albuquerque, New Mexico.Google Scholar
Heilen, Michael P., Nagle, Christopher L., and Altschul, Jeffrey H.. 2008. An Assessment of Archaeological Data Quality: A Report Submitted in Partial Fulfillment of Legacy Resource Management Program Project “To Develop Analytical Tools for Characterizing, Visualizing, and Evaluating Archaeological Data Quality Systematically for Communities of Practice within the Department of Defense.” Technical Report 08-65. Statistical Research, Tucson, Arizona.Google Scholar
Holdaway, Simon, and Fanning, Patricia. 2008. Developing a Landscape History as Part of a Survey Strategy: A Critique of Current Settlement System Approaches based on Case Studies from Western New South Wales, Australia. Journal of Archaeological Method and Theory 15(2):167189.CrossRefGoogle Scholar
Huggett, Jeremy. 2020a. Is Big Digital Data Different? Towards a New Archaeological Paradigm. Journal of Field Archaeology 45(S1):S8S17.CrossRefGoogle Scholar
Huggett, Jeremy. 2020b. Capturing the Silences in Digital Archaeological Knowledge. Information 11(5):278. https://doi.org/10.3390/info11050278.CrossRefGoogle Scholar
Huggett, Jeremy. 2022. Data Legacies, Epistemic Anxieties, and Digital Imaginaries in Archaeology. Digital 2(2):267295. https://doi.org/10.3390/digital2020016.CrossRefGoogle Scholar
Kansa, Eric. 2010. Open Context in Context: Cyberinfrastructure and Distributed Approaches to Publish and Preserve Archaeological Data. SAA Archaeological Record 10(5):1216.Google Scholar
Kansa, Eric. 2012. Openness and Archaeology's Information Ecosystem. World Archaeology 44:498520.CrossRefGoogle Scholar
Kansa, Sarah W. 2015. Using Linked Open Data to Improve Data Reuse in Zooarchaeology. Ethnobiology Letters 6:224231. https://doi.org/10.14237/ebl.6.2.2015.CrossRefGoogle Scholar
Kansa, Sarah W., Atici, Levent, Kansa, Eric C., and Meadow, Richard H.. 2019. Archaeological Analysis in the Information Age: Guidelines for Maximizing the Reach, Comprehensiveness, and Longevity of Data. Advances in Archaeological Practice 8(1):4052.CrossRefGoogle Scholar
Kansa, Eric, and Kansa, Sarah Whitcher. 2021. Digital Data and Data Literacy in Archaeology Now and in the New Decade. Advances in Archaeological Practice 9(1):8185.CrossRefGoogle Scholar
Kansa, Eric, and Kansa, Sarah Whitcher. 2022. Promoting Data Quality and Reuse in Archaeology through Collaborative Identifier Practices. PNAS 119(43):e2109313118. https://doi.org/10.1073/pnas.2109313118.CrossRefGoogle ScholarPubMed
Kelly, Robert L., Mackie, Madeline E., Robinson, Erick, Meyer, Jack, Berry, Michael, Boulanger, Matthew, Codding, Brian F., et al. 2022. A New Radiocarbon Database for the Lower 48 States. American Antiquity 87(3):581590.CrossRefGoogle Scholar
Kintigh, Keith W. 2006. The Promise and Challenge of Archaeological Data Integration. American Antiquity 71(3):567578.CrossRefGoogle Scholar
Kintigh, Keith W. 2018. America's Archaeological Data Keeps Disappearing—Even Though the Law Says the Government Is Supposed to Preserve It. The Conversation, October 17. https://www.pbs.org/newshour/science/americas-archaeology-data-keeps-disappearing-even-though-the-law-says-the-government-is-supposed-to-preserve-it, accessed November 15, 2022.Google Scholar
Kintigh, Keith W., Altschul, Jeffrey H., Beaudry, Mary C., Drennan, Robert D., Kinzig, Ann P., Kohler, Timothy A., Fredrick Limp, W., et al. 2014. Grand Challenges for Archaeology. PNAS 111(3):879880. https://doi.org/10.1073/pnas.1324000111.CrossRefGoogle ScholarPubMed
Kintigh, Keith W., Altschul, Jeffrey H., Kinzig, Ann P., Fredrick Limp, W., Michener, William K., Sabloff, Jeremy A., Hackett, Edward J., Kohler, Timothy A., Ludäscher, Bertram, and Lynch, Clifford A.. 2015. Cultural Dynamics, Deep Time, and Data: Planning Cyberinfrastructure Investments for Archaeology. Advances in Archaeological Practice 3(1):115.CrossRefGoogle Scholar
Kintigh, Keith W., Spielmann, Katherine A., Brin, Adam, Selçuk Candan, K., Clark, Tiffany C., and Peeples, Matthew. 2018. Data Integration in the Service of Synthetic Research. Advances in Archaeological Practice 6(1):30-41. https://doi.org/10.1017/aap.2017.33.CrossRefGoogle Scholar
Kukutai, Tahu, and Taylor, John (editors). 2016. Indigenous Data Sovereignty: Toward an Agenda. Research Monograph No. 38. Centre for Aboriginal Economic Policy Research, Australian National University Press, Canberra.CrossRefGoogle Scholar
Laluk, Nicholas C, Montgomery, Lindsay M., Tsosie, Rebecca, McCleave, Christine, Miron, Rose, Carroll, Stephanie Russo, Aguilar, Joseph, et al. 2022. Archaeology and Social Justice in Native America. American Antiquity 87(4):659682. http://dx.doi.org/10.1017/aaq.2022.59.CrossRefGoogle Scholar
Larson Evan, R., Kipfmueller, Kurt F., and Johnson, Lane B.. 2020. People, Fire, and Pine: Linking Human Agency and Landscape in the Boundary Waters Canoe Area Wilderness and Beyond. Annals of the American Association of Geographers 111:125. https://doi.org/10.1080/24694452.2020.1768042.CrossRefGoogle Scholar
Leckman, Phillip O., and Heilen, Michael. 2023. Our Checkered Past: Sites, Landscapes, Trails, and Transect-Recording Unit Survey. Advances in Archaeological Practice 11(1):1128.CrossRefGoogle Scholar
Lipe, William D. 1974. A Conservation Model for American Archaeology. Kiva 39(3–4):213245.CrossRefGoogle Scholar
Lipe, William D. 2009. Archaeological Values and Resource Management. In Archaeological and Cultural Resource Management: Visions for the Future, edited by Sebastian, Lynne and Lipe, William D., pp. 4163. School for Advanced Research, Santa Fe, New Mexico.Google Scholar
Liu, Pengfei, Loudcher, Sabine, Darmont, Jérôme, and Noûs, Camille. 2021. ArchaeoDAL: A Data Lake for Archaeological Data Management and Analytics. Proceedings of the 25th International Database Engineering & Applications Symposium, edited by Desai, Bipin C., Ullman, Jeffrey, McClatchey, Richard, and Toyoma, Motomichi, pp. 252262. Association for Computing Machinery, New York. https://doi.org/10.1145/3472163.3472266.CrossRefGoogle Scholar
Marwick, Ben. 2017. Computational Reproducibility in Archaeological Research: Basic Principles and a Case Study of Their Implementation. Journal of Archaeological Method and Theory 24:424450.CrossRefGoogle Scholar
Marwick, Ben, d'Alpoim Guedes, Jade, Barton, C. Michael, Bates, Lynsey A., Baxter, Michael, Bevan, Andrew, Bollwerk, Elizabeth A., et al. 2017. Open Science in Archaeology. SAA Archaeological Record 17(4):814.Google Scholar
Marwick, Ben, and Pilaar Birch, Suzanne E.. 2018. A Standard for the Scholarly Citation of Archaeological Data as an Incentive to Data Sharing. Advances in Archaeological Practice 6(2):125143. https://doi.org/10.1017/aap.2018.3.CrossRefGoogle Scholar
McCoy, Mark D. 2020. The Site Problem: A Critical Review of the Site Concept in Archaeology in the Digital Age. Journal of Field Archaeology 45(S1):S18S26.CrossRefGoogle Scholar
McKeague, Peter, Corns, Anthony, Larsson, Åsa, Moreau, Anne, Posluschny, Axel, Van Daele, Koen, and Evans, Tim. 2020. One Archaeology: A Manifesto for the Systematic and Effective Use of Mapped Data from Archaeological Fieldwork and Research. Information 11(4):222. https://doi.org/10.3390/info11040222.CrossRefGoogle Scholar
McManamom, Francis P. 2018a. The Development of Cultural Resource Management in the United States. In New Perspectives in Cultural Resource Management, edited by McManamon, Francis P., pp. 1155. Routledge, New York.Google Scholar
McManamom, Francis P. 2018b. Developments in American Archaeology: Fifty Years of the National Historic Preservation Act. Annual Review of Anthropology 47:553574.CrossRefGoogle Scholar
McManamom, Francis P. 2018c. Digital Archaeological Data: Ensuring Discovery, Access, Use, and Preservation. In Encyclopedia of Global Archaeology, edited by Smith, Claire, pp. 113. Springer, Cham, Switzerland.Google Scholar
McManamon, Francis P., Doershuk, John, Lipe, William D., McCulloch, Tom, Polglase, Christopher, Schlanger, Sarah, Sebastian, Lynne, and Sullivan, Lynne. 2016. Values-Based Management of Archaeological Resources at a Landscape Scale. Advances in Archaeological Practice 4(2):132148.CrossRefGoogle Scholar
McManamon, Francis P., and Ellison, Leigh Anne. 2022. At-Risk Worldwide: Archaeological and Cultural Heritage Digital Data. In Preserving Cultural Heritage in the Digital Age: Sending Out an S.O.S, edited by Lercari, Nicola, Wendrich, Willeke, Porter, Benjamin W., Burton, Margie M., and Levy, Thomas E., pp. 176203. Equinox, Sheffield, United Kingdom.CrossRefGoogle Scholar
McManamon, Francis P., Kintigh, Keith W., Ellison, Leigh Anne, and Brin, Adam. 2017. tDAR: A Cultural Heritage Archive for Twenty-First Century Public Outreach, Research, and Resource Management. Advances in Archaeological Practice 5(3):238249.CrossRefGoogle Scholar
Miller, Myles R., Graves, Tim, Ernst, Moira, and Swanson, Matt. 2018. Deciphering Prehistoric Trails and Unraveling Social Networks in the Tularosa and Hueco Basins. In Late Prehistoric Hunter-Gatherers and Farmers of the Jornada Mogollon, edited by Rocek, Thomas R. and Kenmotsu, Nancy A., pp. 97123. University Press of Colorado, Louisville.Google Scholar
Miller, Myles R., Kenmotsu, Nancy A., and Landreth, Mel R. (editors). 2009. Significance and Research Standards for Prehistoric Archaeological Sites at Fort Bliss: A Design for the Evaluation, Management, and Treatment of Cultural Resources. Cultural Resources Report No. 05-16. Submitted to the Environmental Division, Garrison Command, Fort Bliss, Texas. GMI Report No. 697EP. Geo-Marine, El Paso, Texas.Google Scholar
Mills, Barbara, Ram, Sudha, Clark, Jeffery, Ortman, Scott, and Peeples, Matthew. 2020. cyberSW Version 1.0. Archaeology Southwest, Tucson, Arizona.Google Scholar
Moore, Ray, and Richards, Julian. 2015. Here Today, Gone Tomorrow: Open Access, Open Data and Digital Preservation. In Open Source Archaeology, edited by Wilson, Andrew T. and Edwards, Ben, pp. 3043. De Gruyter Open, Warsaw, Poland. https://doi.org/10.1515/9783110440171-004.Google Scholar
Neusius, Sarah W., Styles, Bonnie W., Peres, Tanya M., Walker, Renee B., Crothers, George M., Smith, Beverley A., and Colburn, Mona L.. 2019. Zooarchaeological Database Preservation, Multiscalar Data Integration, and the Collaboration of the Eastern Archaic Faunal Working Group. Advances in Archaeological Practice 7(4):409422.CrossRefGoogle Scholar
Nicholas, George P., and Bannister, Kelly P.. 2004. Copyrighting the Past? Emerging Intellectual Property Rights Issues in Archaeology. Current Anthropology 45(3):327350.CrossRefGoogle Scholar
Nicholson, Christopher, Kansa, Sarah, Gupta, Neha, and Fernandez, Rachel. 2023. Will It Ever Be FAIR? Making Archaeological Data Findable, Accessible, Interoperable, and Reusable. Advances in Archaeological Practice 11(1):6375.CrossRefGoogle Scholar
Niven, Kieron. 2011. Planning for the Creation of Digital Data. In Guides to Good Practice. Archaeology Data Service / Digital Antiquity. Electronic document, https://guides.archaeologydataservice.ac.uk/g2gp/CreateData_1-0, accessed November 15, 2022.Google Scholar
Ogar, Edwin, Pecl, Gretta, and Mustonen, Tero. 2020. Science Must Embrace Traditional and Indigenous Knowledge to Solve Our Biodiversity Crisis. One Earth 3(2):162165.CrossRefGoogle Scholar
O'Leary, Beth L., Kludt, Trevor J., Church, Tim, and Mauldin, Raymond P. (editors). 1997. The McGregor Guided Missile Range Survey Project, New Mexico, Vol. I: The Archaeology of Landscape-General Survey. Fort Bliss Project No. 96-28. Archaeological Technical Report No. 14. Anthropological Research Center, University of Texas, El Paso.Google Scholar
Ortman, Scott G. 2019. A New Kind of Relevance for Archaeology. Frontiers in Digital Humanities 6(16). https://doi.org/10.3389/fdigh.2019.00016.CrossRefGoogle Scholar
Ortman, Scott G., and Altschul, Jeffrey H.. 2023. What North American Archaeology Needs to Take Advantage of the Digital Data Revolution. Advances in Archaeological Practice 11(1):90103.CrossRefGoogle Scholar
Ortman, Scott G., Smith, Michael E., Lobo, José, and Bettencourt, Luís M. A.. 2020. Why Archaeology Is Necessary for a Theory of Urbanization. Journal of Urban Archaeology 1(1):151167.CrossRefGoogle Scholar
Pavel, Cătălin. 2010. Describing and Interpreting the Past: European and American Approaches to the Written Record of the Excavation. Editura Universităţii din Bucuresti, Bucharest, Romania.Google Scholar
Pavel, Cătălin. 2012. Archaeological Recording: Form and Content, Theory and Practice. Atek Na [En La Tierra] 2:3374.Google Scholar
Plog, Stephen, Plog, Fred, and Wait, Walter. 1978. Decision-Making in Modern Surveys. Advances in Archaeological Method and Theory 1:384421.Google Scholar
Pluckhahn, Thomas J., and Wallis, Neill J.. 2017. Social Networks and Networked Scholars: An Open-Access Database of Paddle Designs from Pottery of the Woodland Period in the American Southeast. Advances in Archaeological Practice 5(2):159169.CrossRefGoogle Scholar
Richards, Julian D. 2017. Twenty Years Preserving Data: A View from the United Kingdom. Advances in Archaeological Practice 5(3):227237. https://doi.org/10.1017/aap.2017.11.CrossRefGoogle Scholar
Richards, Julian D., Austin, Tony, and Hardman, Catherine. 2010. Covering the Costs of Digital Curation. Heritage Management 3:255263.CrossRefGoogle Scholar
Robinson, William J., and Cameron, Catherine M.. 1991. A Directory of Tree-Ring Dated Prehistoric Sites in the American Southwest. Laboratory of Tree-Ring Research, University of Arizona, Tucson.Google Scholar
Robinson, Erick, Nicholson, Christopher, and Kelly, Robert L.. 2019. The Importance of Spatial Data to Open-Access National Archaeological Databases and the Development of Paleodemography Research. Advances in Archaeological Practice 7(4):395408.CrossRefGoogle Scholar
Roosevelt, Christopher H., Cobb, Peter, Moss, Emanuel, Olson, Brandon R., and Ünlüsoy, Sinan. 2015. Excavation Is Destruction Digitization: Advances in Archaeological Practice. Journal of Field Archaeology 40(3):325346. https://doi.org/10.1179/2042458215Y.0000000004.CrossRefGoogle Scholar
Ross, Anne, Sherman, Kathleen Pickering, Snodgrass, Jeffrey G., Delcore, Henry D., and Sherman, Richard. 2011. Indigenous Peoples and the Collaborative Stewardship of Nature: Knowledge Binds and Institutional Conflicts. Left Coast Press, Walnut Creek, California.Google Scholar
Schiffer, Michael B., Sullivan, Alan P., and Klinger, Timothy C.. 1978. The Design of Archaeological Surveys. World Archaeology 10:128.CrossRefGoogle Scholar
Schlanger, Sarah H. 2023. More Than Meets the Eye: Integrating the Management of Landscape Character and Archaeological Resources for Culturally Significant Landscapes. Advances in Archaeological Practice 11(1):4251.CrossRefGoogle Scholar
Schlanger, Sarah, Wilshusen, Richard, and Roberts, Heidi. 2015. From Mining Sites to Mining Data: Archaeology's Future. Kiva 81(1–2):8099.CrossRefGoogle Scholar
Seaman, Timothy J., Doleman, William H., and Chapman, Richard C. (editors). 1988. The Border Star 85 Survey: Toward an Archaeology of Landscapes. Office of Contract Archeology, University of New Mexico, Albuquerque.Google Scholar
Sheehan, Beth. 2015. Comparing Digital Archaeological Repositories; tDAR Versus Open Context. Behavioral & Social Science Librarian 34(3):173213.CrossRefGoogle Scholar
Shott, Michael J. 1992. Commerce or Service: Models of Practice in Archaeology. In Quandaries and Quests: Visions of Archaeology's Future, edited by Wandsnider, LuAnn, pp. 924. Occasional Paper No. 20. Center for Archaeological Investigation, Southern Illinois University, Carbondale.Google Scholar
Shott, Michael J. 1995. Reliability of Archaeological Records on Cultivated Surfaces: A Michigan Case Study. Journal of Field Archaeology 22(4):475-490. https://doi.org/10.2307/530195.Google Scholar
Shott, Michael J., Tiffany, Joseph A., Doershuk, John F., and Titcomb, Jason. 2002. The Reliability of Surface Assemblages: Recent Results from the Gillett Grove Site, Clay County, Iowa. Plains Anthropologist 47:165182.CrossRefGoogle Scholar
SRI Foundation. 2020. SRI Foundation Estimation of the US Spending for Cultural Resource Management and Archaeology for Fiscal Year 2020. SRI Foundation, Rio Rancho, New Mexico. Electronic document, http://srifoundation.org/SRIFFY2020CRMEstimate.pdf, accessed August 8, 2022 .Google Scholar
Stewart, Sarah Tyrrell. 2006. Walking in Cyprus: Ancient Landscapes and Modern Bias. PhD dissertation, Department of Anthropology, University of Toronto, Toronto.Google Scholar
Stoffle, R., Arnold, R., Van Vlack, K., O'Meara, S., and Savage, J.. 2009. Black Mountain: Traditional Uses of a Volcanic Landscape, Vol. 2. Prepared for U.S. Air Force - Air Combat Command Nevada Test and Training Range Native American Program and the Pruitt and Associates. Bureau of Applied Research in Anthropology, University of Arizona, Tucson.Google Scholar
Toupal, Rebecca S., Nives Zedeño, M., Stoffle, Richard W., and Barabe, Patrick. 2001. Cultural Landscapes and Ethnographic Cartographies: Scandinavian-American and American Indian Knowledge of the Land. Environmental Science & Policy 4:171184.CrossRefGoogle Scholar
van Schilfgaarde, Lauren. 2020. The Need for Confidentiality within Tribal Cultural Resource Protection. Tribal Legal Development Clinic, UCLA School of Law, Native Nations Law & Policy Center. Electronic document, https://law.ucla.edu/sites/default/files/PDFs/Native_Nations/239747_UCLA_Law_publications_Confidentiality_R2_042021.pdf, accessed August 15, 2022.Google Scholar
Wandsnider, LuAnn, and Camilli, Eileen. 1992. The Character of Surface Archaeological Deposits and Its Influence on Survey Accuracy. Journal of Field Archaeology 19(2):169188. https://doi.org/10.2307/529977.Google Scholar
Watkins, Joe, and Ferguson, T. J.. 2005. Working with and Working for Indigenous Communities. In Handbook of Archaeological Methods, Volume I, edited by Maschner, Herbert D. G. and Chippindale, Christopher, pp. 13721405. AltaMira Press, Lanham, Maryland.Google Scholar
Watts, Joshua. 2011. Policies, Preservation, and Access to Digital Resources: The Digital Antiquity 2010 National Repositories Survey. Reports in Digital Archaeology Number 2. Center for Digital Antiquity, Arizona State University, Tempe.Google Scholar
Wells, Joshua J., Kansa, Eric C., Kansa, Sarah W., Yerka, Stephen J., Anderson, David G., Bissett, Thaddeus G., Myers, Kelsey Noack, and Carl DeMuth, R.. 2014. Web-Based Discovery and Integration of Archaeological Historic Properties Inventory Data: The Digital Index of North American Archaeology (DINAA). Literary and Linguistic Computing 29(3):349360.CrossRefGoogle Scholar
Wilkinson, Mark D., Dumontier, Michel, Aalbersberg, IJsbrand Jan, Appleton, Gabrielle, Axton, Myles, Baak, Arie, Blomberg, Niklas, et al. 2016. The FAIR Guiding Principles for Scientific Data Management and Stewardship. Scientific Data 3. https://doi.org/10.1038/sdata.2016.18.CrossRefGoogle ScholarPubMed
Wilkinson, Mark D., Dumontier, Michel, Sansone, Susanna-Assunta, da Silva Santos, Luiz Olavo Bonino, Prieto, Mario, Batista, Dominique, McQuilton, Peter, et al. 2019. Evaluating FAIR Maturity through a Scalable, Automated, Community-Governed Framework. Scientific Data 6:174. https://doi.org/10.1038/s41597-019-0184-5.Google ScholarPubMed
Williams, Justin P., and Williams, Rachel D.. 2019. Information Science and North American Archaeology: Examining the Potential for Collaboration. Information Research 24(2):119.Google Scholar
Wilshusen, Richard H., Heilen, Michael, Catts, Wade, de Dufour, Karen, and Jones, Bradford. 2016. Archaeological Survey Data Quality, Durability, and Use in the United States. Advances in Archaeological Practice 4(2):106117.CrossRefGoogle Scholar
Wright, Holly, and Richards, Julian D.. 2018. Reflections on Collaborative Archaeology and Large-Scale Online Research Infrastructures. Journal of Field Archaeology 43(S1):S60S67. https://doi.org/10.1080/00934690.2018.1511960.CrossRefGoogle Scholar
Yakel, Elizabeth, Faniel, Ixchel M., and Maiorana, Zachary J.. 2019. Virtuous and Vicious Circles in the Data Life-Cycle. Information Research 24(2):821.Google Scholar
York, Jeremy, Gutmann, Myron, and Berman, Francine. 2018. What Do We Know about the Stewardship Gap? Data Science Journal 7(19):117. https://doi.org/10.5334/dsj-2018-019.Google Scholar
Zedeño, María Nieves, Austin, Diane, and Stoffle, Richard. 1997. Landmark and Landscape: A Contextual Approach to the Management of American Indian Resources. Culture & Agriculture 19(3):123129.CrossRefGoogle Scholar