267
AI Prompts: Tools for Optimizing Scientific Research
Los Prompts de IA: Herramientas para la Optimización de la Investigación Científica
In the last decade, artificial intelligence (AI) has emerged as a transformative agent in producing
scientific knowledge, impacting multiple disciplines in a transversal way. The research's purpose
is to analyze the impact of AI-based prompts in optimizing data processing and structuring. A
qualitative approach was adopted, based on the interpretive paradigm and hermeneutic method,
with a descriptive cross-sectional design. The sample representative consisted of 25 academic
researchers. For information collection, semi-structured interviews were used, whose analysis
was carried out through open coding and NVivo software, allowing the identification of
emerging patterns and significant trends. The results show that AI increases efficiency in data
management and favors the identification of new lines of scientific inquiry. In addition, a notable
reduction in processing times and increased precision in analyzing large volumes of information
were observed. Consequently, the tools are consolidated as notable resources for contemporary
research, particularly in contexts where the management of massive data and the optimization
of comparative methodologies are decisive. It is recommended that they be incorporated into all
phases of the knowledge-generation process and that ethical and regulatory frameworks be
established to regulate the use of AI in research, promoting its integration as a complementary
tool and not as a substitute for human reasoning in the construction of scientific knowledge.
Keywords: Prompts, AI, tools, optimization, scientific research.
¹Grupo Docentes 2.0 C.A.
¹https://orcid.org/0000-0002-2602-5199
¹Estados Unidos de América
Mujica-Sequera, R. (2025). Los Prompts de IA:
Herramientas para la Optimización de la
Investigación Científica. Revista Tecnológica-
Educativa Docentes 2.0, 18(1), 267-277.
https://doi.org/10.37843/rted.v18i1.616
R. Mujica-Sequera, "Los Prompts de IA:
Herramientas para la Optimización de la
Investigación Científica", RTED, vol. 18, n.°1, pp.
267-277, may. 2025.
https://doi.org/10.37843/rted.v18i1.616
Ruth M. Mujica-Sequera¹
29/mayo/2025
En la última década, la Inteligencia Artificial (IA) ha emergido como un agente transformador
en la producción de conocimiento científico, incidiendo de manera transversal en múltiples
disciplinas. La investigación tuvo como propósito analizar el impacto de los prompts basados
en IA en la optimización del procesamiento y estructuración de datos. Se adoptó un enfoque
cualitativo, sustentado en el paradigma interpretativo y método hermenéutico, con un diseño
descriptivo de corte transversal. La muestra representativa estuvo conformada por 25
investigadores académicos. Para la recopilación de información, se emplearon entrevistas
semiestructuradas, cuyo análisis se efectuó mediante codificación abierta y el uso del software
NVivo, permitiendo la identificación de patrones emergentes y tendencias significativas. Los
resultados evidencian que los prompts de IA no solo incrementan la eficiencia en la gestión de
datos, sino que también favorecen la identificación de nuevas líneas de indagación científica.
Además, se observó una notable reducción en los tiempos de procesamiento y un incremento en
la precisión del análisis de grandes volúmenes de información. En consecuencia, las
herramientas se consolidan como recursos notables para la investigación contemporánea,
particularmente en contextos donde el manejo de datos masivos y la optimización de
metodologías comparativas resultan determinantes. Se recomienda su incorporación en todas las
fases del proceso de generación de conocimiento y se sugiere establecer marcos éticos y
normativos que regulen el uso de la IA en la investigación, promoviendo su integración como
una herramienta complementaria y no como un sustituto del razonamiento humano en la
construcción del conocimiento científico.
Palabras claves: Prompts, IA, herramientas, optimización, investigación científica.
10/octubre/2024
10/febrero/2025
desde 267- 277
AI Prompts: Tools for Optimizing Scientific
Research
Mujica-Sequera, R. (2025). Los Prompts de IA: Herramientas para la Optimización de la Investigación Científica. Revista Tecnológica-Educativa Docentes 2.0, 18(1), 267-
277. https://doi.org/10.37843/rted.v18i1.616
268
268
Introduction
In recent years, Artificial Intelligence (AI) has
revolutionized the methodological approach in various
scientific disciplines, redefining how data is analyzed,
and processes are automated. Its integration has proven
to be a key resource for improving efficiency and
precision in producing knowledge. Among the most
promising advances are AI prompts, which allow
researchers to interact with advanced systems to
formulate hypotheses, analyze large volumes of
information, and extract relevant data more quickly and
accurately.
However, adopting these tools faces substantial
challenges, mainly due to the lack of transparency in
integrating AI technologies in the academic field. This
gap creates a dissonance between their theoretical
potential and practical application, translating into a
persistent dependence on traditional analytical
methods. Consequently, the pace of scientific
production and the analytical depth of studies are
limited. Resistance to the use of AI, exacerbated by a
lack of specialized training and a general lack of
knowledge about its capabilities, restricts the
transformation of academic work and prevents
maximizing benefits such as the automation of
repetitive tasks and the efficient processing of large
volumes of data.
Previous research, such as that of Smith (2021),
Johnson (2020), and Brown (2019), has shown that AI
prompts not only favor the generation of new scientific
questions but also optimize the identification of
complex patterns in data, significantly accelerating
literature review and comparative analysis. The
findings underline the innovative capacity of AI to
enhance traditional methods, allowing researchers to
focus on aspects of greater analytical and creative
complexity. However, the widespread adoption of these
technologies still faces considerable barriers,
particularly in training and familiarization with their
operation. In this context of accelerated technological
advancement, overcoming obstacles to ensure the
effective integration of AI into academic research is
imperative.
The research's purpose is to analyze the impact
of AI-based prompts in optimizing data processing and
structuring. In this sense, the study is oriented around
the following central question: How can AI prompts
improve efficiency and accuracy in scientific research?
The study seeks to establish a solid conceptual
framework that identifies the areas in which AI can
generate the greatest impact, thus facilitating its
incorporation into academic research processes.
Methodology
A study was carried out within the interpretive
paradigm in response to the stated objective and to
contribute to generating knowledge about the benefits
of AI prompts in research. According to Sandoval
(2002), this paradigm is oriented towards
"understanding the meaning of human actions within
their social context, allowing the researcher to interpret
the experiences of the subjects studied" (p. 67). In this
sense, the study focused on exploring and analyzing
researchers' perceptions regarding the use of AI
prompts to identify their impact on the optimization of
analytical processes and the formulation of hypotheses
in the scientific field.
The method used was the hermeneutic one,
which, according to Gadamer (1997), is based on the
"interpretation of texts and phenomena through
dialogue and contextual understanding, providing a
deep interpretation of the data" (p. 123). The method
allowed us to analyze the participants' responses and
understand the meanings beyond the explicit words by
considering the context and individual experiences of
each subject. Through the hermeneutic process, it was
possible to identify underlying patterns and emerging
themes that would not have been visible through a
superficial analysis. It also facilitated the construction
of a coherent narrative by connecting the participants'
perceptions with existing theories. This way, deep and
well-founded conclusions were drawn, providing a
comprehensive and in-depth view of the phenomena
studied.
The research approach was qualitative, which,
according to Denzin and Lincoln (2018), seeks to
"explore and understand phenomena from the
perspective of participants, prioritizing depth over
statistical generalization" (p. 45). The approach focused
on capturing the complexities and nuances of human
experiences, which allowed the researchers to immerse
themselves in the context of each individual and obtain
a detailed view of their perceptions. Unlike quantitative
methods, which seek replicable and generalizable data,
the qualitative approach offers a rich and holistic view
of phenomena by favoring the deep interpretation of
social and cultural realities.
According to Merriam (2009), the objective of
the qualitative approach "is to understand the how and
why behind actions and behaviors, making it an
essential tool for research in dynamic and complex
areas" (p. 12). In the present study, the qualitative
approach allowed for obtaining a detailed view of the
researchers' perceptions of the benefits of AI prompts.
The design was of the descriptive-interpretive type,
which, according to Taylor & Bogdan (1986), focuses
on "describing phenomena as they occur in their natural
context, interpreting the meaning of said phenomena
through qualitative analysis" (p. 78). In addition, it was
a cross-sectional study since it was conducted at a
Mujica-Sequera, R. (2025). Los Prompts de IA: Herramientas para la Optimización de la Investigación Científica. Revista Tecnológica-Educativa Docentes 2.0, 18(1), 267-
277. https://doi.org/10.37843/rted.v18i1.616
269
AI Prompts: Tools for Optimizing Scientific
Research
269
single point in time, which allowed "capturing a
snapshot of the participants' current perceptions"
(Hernández et al., 2014, p. 102).
The population under study consisted of 100
academic researchers participating in the Research
Seminar diploma course who have integrated artificial
intelligence tools into their research processes. The
selection of this group was based on their recent and
direct experience with advanced technologies, which
guaranteed the relevance and timeliness of the data
collected. According to Kerlinger (1986), the
population "is the set of individuals who possess the
necessary characteristics to be included in the study" (p.
84). In this case, only researchers with proven
experience in using AI were selected, which allowed for
a detailed analysis of its benefits and challenges in the
academic field.
In qualitative research, the sample size is
determined based on theoretical saturation, a widely
used criterion to define the point at which data
collection ceases to provide significant new
information to the study (Glaser & Strauss, 1967, p. 61).
In the present work, the sample of 25 academic
researchers was strategically selected according to the
level of technological experience and belonging to
different disciplines to ensure sufficient diversity of
perspectives, allowing the identification of recurring
patterns in the perception and application of artificial
intelligence prompts in scientific research. According
to Morse (1994), theoretical saturation is reached when
the data obtained begins to repeat the same categories
without new codes or relevant dimensions emerging in
the qualitative analysis. In this sense, the selected
sample was adequate since it allowed a deep
exploration of the participants' experiences without
compromising the analytical integrity of the study.
The interview process was designed with
questions that explored both the perceived benefits and
challenges of implementing AI prompts, which
facilitated the identification of relevant categories. The
categories emerged from the arguments recurrently
addressed by the interviewees and were validated
through a rigorous qualitative analysis, ensuring that
they faithfully reflected the collective perceptions of the
participants.
The data collection instrument consisted of 10
open questions strategically designed to explore in
depth the perceptions and experiences of researchers
regarding the use of artificial intelligence prompts in
their research processes. The main thematic axes
addressed in the interviews included (1) efficiency in
data analysis, (2) generation of new hypotheses, (3)
improvement in the accuracy of the results, (4)
facilitation in the bibliographic review, and (5)
challenges in technological integration.
A neutral and open-ended question design was
applied to minimize potential bias in responses,
avoiding formulations that suggested a positive or
negative assessment of the AI prompts. In addition, a
flexible guide was used that allowed the interview to be
adapted to the discourse of each participant,
encouraging spontaneous and unrestricted responses.
Regarding data processing, the interviews were
recorded, transcribed verbatim, and subjected to a
cross-validation process, in which the researchers
reviewed the transcripts to ensure the fidelity of the
information. Subsequently, the data were analyzed
through open and axial coding with NVivo, which
allowed the identification of emerging patterns and the
establishment of relationships between key concepts.
This methodological approach ensured analytical rigor
and coherence in the interpretation of the findings,
guaranteeing the reliability of the study.
Likewise, the validity of the results in qualitative
studies does not depend on the sample size per se but
on the richness and depth of the data collected
(Creswell, 2013, p. 157). In the context of the present
study, the purposive sampling strategy made it possible
to ensure that the selected participants had direct and
recent experience with AI tools, thus ensuring that the
findings were representative within the field
investigated. The choice of 25 participants is in line
with methodological recommendations in qualitative
studies, where it has been shown that between 20 and
30 in-depth interviews are usually sufficient to reach
saturation in research seeking to understand complex
phenomena (Guest et al., 2006, p. 75). Therefore, the
selected sample size is methodologically sound and
allows for drawing well-founded and transferable
conclusions within the academic context analyzed.
The technique used was the semi-structured
interview validated by experts, according to Quivy &
Campenhoudt (2006), which allows the researcher to
"obtain detailed information on the topics of interest,
while leaving room for participants to express their
opinions freely" (p. 89). These provided an invaluable
opportunity to identify emerging and unforeseen
aspects, significantly enriching the data analysis. The
flexibility inherent in semi-structured interviews
allowed participants to expand their responses,
facilitating a deep understanding of the benefits and
challenges associated with AI. Likewise, the
instrument's structure guaranteed coverage of the key
arguments of the study while promoting an
environment for the personal and professional
experiences of the interviewees to nourish the dialogue,
favoring an open and enriching exchange.
A methodological and researcher triangulation
approach was used to guarantee the validity and
reliability of the study data, strengthening the
interpretation of the results and reducing potential
Mujica-Sequera, R. (2025). Los Prompts de IA: Herramientas para la Optimización de la Investigación Científica. Revista Tecnológica-Educativa Docentes 2.0, 18(1), 267-
277. https://doi.org/10.37843/rted.v18i1.616
270
AI Prompts: Tools for Optimizing Scientific
Research
270
biases in the qualitative analysis. Semi-structured
interviews, open coding, and NVivo software analysis
were used for methodological triangulation, ensuring
the data were analyzed from several angles.
Additionally, researcher triangulation was employed, in
which two specialists in qualitative technique
independently examined the data's coding and
classification, contrasting their views and reaching a
consensus to settle disagreements. This technique
improved the study's reliability by ensuring uniformity
in the creation of emerging patterns and reducing
subjectivity in the category assignment.
According to Patton (1999), triangulation of
methods and researchers reinforces the credibility of
qualitative research by allowing for a more rigorous
contrast of data and their interpretations. In addition,
the member-checking technique was applied, providing
some participants with preliminary summaries of the
findings to validate the interpretation of their responses
and corroborate that they faithfully reflected their
experiences with AI ads. These methodological
strategies strengthened the reliability of the study,
ensuring that the results obtained were representative
and based on a systematic and transparent analysis.
The data analysis was carried out through open
coding, a process that, according to Strauss & Corbin
(2002), consists of the "systematic segmentation of data
into conceptual units, allowing the identification of
categories, the detection of recurring patterns and the
generation of relationships between emerging
concepts" (p. 137). The procedure enabled the analysis
of participants' responses to key arguments, facilitating
the identification of dominant and recurring trends
associated with using artificial intelligence prompts in
the research field.
The selection of the categories was based on the
grouping of data according to recurring patterns and
emerging concepts based on the responses obtained in
the interviews (Strauss & Corbin, 2002). Key narratives
were identified as the transcripts were analyzed,
reflecting the researchers' experiences using AI
Prompts. As a result, the coding process allowed the
findings to be classified into five essential categories:
efficiency in data analysis, generation of new
hypotheses, improvement in the accuracy of the results,
facilitation in the bibliographic review, and challenges
in technological integration (see Table 1).
Table 1
Data Categorization
Category
Description
Reduction in analysis time.
Significant acceleration in processing large volumes of information.
Generation of new hypotheses.
Facilitation in the creation of new assumptions and connections between variables.
Improved accuracy of results.
Greater accuracy in identifying patterns and trends in data.
Facilitation in bibliographic
review.
Simplification in the search and organization of scientific literature.
Challenges in technological
integration.
Technology learning curve and training need to maximize the use of prompts.
Note. Presents the five key categories that emerged from the qualitative analysis of the benefits researchers reported in using
AI prompts, prepared by Mujica-Sequera (2024).
Initially, a keyword and lexical frequency analysis was
performed, which allowed the identification of the most
prevalent terms in the researchers’ discourses, thus
establishing an empirical basis for subsequent coding.
From this exploratory phase, an NVivo-assisted open
coding process was implemented, segmenting the data
into meaningful units and generating emerging
categories from the discourse structure analyzed. The
categories were consolidated through an iterative axial
coding approach, establishing hierarchical and
transversal relationships between the identified themes,
which facilitated the construction of a comprehensive
analytical model on the integration of AI in research.
Furthermore, the use of NVivo (see Figure 1) enabled
the visualization of thematic associations through the
generation of conceptual maps and categorical
interconnection models, strengthening the analytical
interpretation and ensuring the internal coherence of the
study. The structured process allowed the discovery of
previously unnoticed subthemes and nuances, enriching
the depth of the analysis and providing a more holistic
understanding of the phenomenon studied. Data
triangulation and contrast of emerging categories with
existing literature strengthened the interpretive validity
of the findings, ensuring their methodological
robustness.
Mujica-Sequera, R. (2025). Los Prompts de IA: Herramientas para la Optimización de la Investigación Científica. Revista Tecnológica-Educativa Docentes 2.0, 18(1), 267-
277. https://doi.org/10.37843/rted.v18i1.616
271
AI Prompts: Tools for Optimizing Scientific
Research
271
Figure 1
Conceptual Map: Relationships between Categories
Note. Keywords and lexical frequency are displayed, prepared by Mujica-Sequera (2024).
Results
The results obtained from the interviews show a
clear trend toward optimizing research processes using
artificial intelligence prompts. Most participants (85%)
indicated that the integration of these tools has
significantly improved efficiency in analyzing large
volumes of data. This advance has resulted in a
substantial reduction in processing times, allowing
researchers to focus greater efforts on their projects'
analytical and creative phases, thus enhancing the depth
and quality of their studies.
Figure 2
Impact of AI Prompts on Research
Note. The main benefits researchers reported in using AI
prompts in their research processes are displayed visually.
Prepared by Mujica-Sequera (2024).
In Figure 2, the main benefit highlighted by AI
prompts is the reduction in analysis time, a finding that
is consistent with the responses obtained during the
interviews. Most participants highlighted how AI has
facilitated the acceleration of routine data processing
tasks, thus improving the overall efficiency of research
work. The result suggests that AI has been a key
instrument in transforming researchers’ workflow,
freeing up time for critical analysis and interpretation
of results.
The improvement in the accuracy of results,
which is also significant, demonstrates that AI prompts
have substantially increased the accuracy of analyses.
Participants reported that thanks to AI, they could
detect hidden patterns and complex correlations that
would likely have been missed with traditional
methods. The process saves time and ensures that
findings are robust and accurate. Furthermore, using AI
increases researchers’ ability to handle large volumes
of data with more detail and rigor. Advancement
emphasizes the value of AI prompts in strengthening
the validity and reliability of scientific studies, allowing
for greater confidence in the results obtained.
The generation of new hypotheses is another key
area, as illustrated in Figure 1, which highlights how
researchers use AI to optimize existing processes, open
new lines of inquiry, and formulate innovative
Mujica-Sequera, R. (2025). Los Prompts de IA: Herramientas para la Optimización de la Investigación Científica. Revista Tecnológica-Educativa Docentes 2.0, 18(1), 267-
277. https://doi.org/10.37843/rted.v18i1.616
272
AI Prompts: Tools for Optimizing Scientific
Research
272
questions. AI prompts have made it possible to identify
relationships and connections between variables that
were not previously apparent, thus fostering greater
creativity in hypothesis formulation. In this sense, the
innovative use of AI makes it possible to transcend
traditional approaches, expanding the scope and depth
of academic research. Likewise, its role in generating
new hypotheses reaffirms its potential to drive
innovation in various scientific disciplines,
consolidating itself as a key resource for expanding
knowledge.
On the other hand, integrating these technologies
faces significant challenges, especially regarding the
training of researchers to maximize the use of AI tools.
While its potential is widely recognized, the initial
learning curve represents an obstacle for some
academics, hindering its effective adoption. The lack of
specific training in using these technologies is
positioned as one of the main barriers, highlighting the
need to develop training programs specifically aimed at
the research community. In addition, the scarcity of
institutional resources to support training processes
further limits access to and use of AI in the academic
field. In this context, the importance of investing in
ongoing training initiatives that allow researchers to
overcome these barriers and fully exploit the potential
of artificial intelligence in generating knowledge is
evident.
Table 2
Reported Benefits of Using AI Prompts in Research
Benefit
Researchers
Reduction in analysis time
85%
Improvement in the accuracy of results
75%
Generation of new hypotheses
70%
Facilitation in bibliographic review
65%
Challenges in technological integration
40%
Note. The main benefits researchers identified in using AI prompts are summarized. Prepared by Mujica-Sequera (2024).
The descriptive analysis of the data obtained in
this study (see Table 2) revealed that most researchers
recognize a positive impact on efficiency and accuracy
derived from using artificial intelligence prompts in
their research. The percentages recorded in the main
categories are significant: 85% of the participants
highlighted the reduction in analysis time, while 75%
pointed out an improvement in the accuracy of the
results. Likewise, 70% of the researchers underlined the
capacity of AI prompts to facilitate the generation of
new hypotheses, and 75% recognized their usefulness
in simplifying the literature review process. The
findings show the key role of AI in optimizing both the
workflow and the quality of the results obtained in
academic research.
One of the most relevant aspects identified by
75% of the participants was the improvement in the
accuracy of the results. The researchers emphasized
that AI prompts allowed them to identify patterns and
trends in the data more accurately, leading to more
reliable findings with a smaller margin of error.
Consequently, the optimization of the analysis
strengthened the validity of the conclusions obtained in
their studies, increasing the methodological robustness
and reliability of the results.
Regarding the generation of new hypotheses,
70% of the interviewees highlighted that AI prompts
facilitated the formulation of new lines of research by
allowing the exploration of novel relationships between
previously unconsidered variables. This finding
reaffirms the role of AI as an advanced analytical tool
and a catalyst for innovation in scientific research,
promoting the opening of new perspectives and
methodological approaches.
On the other hand, the bibliographic review
process was also optimized through AI prompts, with
75% of researchers indicating that these tools
streamlined the search and organization of scientific
literature, significantly reducing the time spent on this
task. However, the technological integration of AI
prompts still faces challenges, as 40% of respondents
reported difficulties, mainly due to inadequate training
and the learning curve required for efficient use. The
results underline the need to develop training strategies
that allow researchers to maximize the use of these
technologies in their academic practices.
Regarding the inferential analysis, the statistical
results confirm the assumption made at the beginning
of the research. It was assumed that AI prompts would
improve the efficiency and accuracy of research
processes, which were validated by the percentages
obtained. 85% of the researchers stated that prompts
significantly reduced analysis time, confirming that AI
speeds up routine processes. Likewise, the assumptions
that AI prompts would improve accuracy in data
analysis were confirmed by the results, as 75% of the
participants reported improvements in pattern
identification and the reliability of their analyses.
Mujica-Sequera, R. (2025). Los Prompts de IA: Herramientas para la Optimización de la Investigación Científica. Revista Tecnológica-Educativa Docentes 2.0, 18(1), 267-
277. https://doi.org/10.37843/rted.v18i1.616
273
AI Prompts: Tools for Optimizing Scientific
Research
273
Therefore, the inferential results strongly support the
assumption that AI prompts are a valuable tool in
academic research.
Despite the numerous perceived benefits, some
results were inconclusive or highlighted areas of
opportunity in integrating AI prompts. 40% of
researchers pointed out difficulties in the technological
implementation of the tools, mainly attributable to the
lack of training and the learning curve required for their
effective use. While this percentage is significant, the
data was not precise enough to determine what types of
training or specific resources would most effectively
mitigate the obstacles. Likewise, there was insufficient
evidence to establish whether researchers with prior
experience in AI achieved greater benefits than those
new to its use, suggesting the need for additional studies
that delve deeper into this issue.
Among the main challenges mentioned is the
lack of access to specialized software, which limits the
possibility of experimenting with advanced tools and
restricts their application in academic environments
with insufficient technological infrastructure. There
was also evidence of resistance to change on the part of
some researchers, particularly those with established
traditional methodologies, who expressed skepticism
regarding the reliability and real impact of AI prompts
on knowledge production. Another recurring obstacle
was the steep learning curve and lack of specific
training, making it difficult to appropriate these tools
and generating dependence on AI specialists for
effective implementation. In addition, technical
problems were identified related to the compatibility of
the prompts with scientific databases and information
management systems, which restricted their fluid
integration into the research workflow.
The study results confirm that AI prompts are
key in improving efficiency and accuracy within
research processes. Regarding efficiency, researchers
reported a significant reduction in the time required for
tasks such as collecting, organizing, and analyzing large
volumes of data. The ability to automate routine and
repetitive processes allowed academics to focus their
efforts on more complex analytical and conceptual
aspects. This finding is reflected in the fact that 85% of
participants indicated that the use of AI considerably
reduced analysis times, thus speeding up the overall
development of their research.
Regarding accuracy, AI prompts proved to be
effective tools for identifying patterns and relationships
in data that, with traditional methods, could go
unnoticed. Researchers highlighted that AI enables
more detailed and accurate analysis, reducing the
margin of error and improving the results' reliability.
75% of respondents emphasized that the accuracy in
identifying trends and correlations improved
significantly with implementing these tools. The
findings show that AI speeds up research processes and
ensures that the results are more robust and reliable.
Furthermore, AI prompts facilitate the formulation of
new hypotheses from data analysis, allowing
researchers to explore previously unconsidered lines of
inquiry. This aspect drives creativity and innovation
within the research process, strengthening scientists'
ability to make meaningful discoveries.
While the benefits of AI prompts in terms of
efficiency and accuracy are evident, their widespread
adoption still faces challenges that require appropriate
strategies to be overcome. Based on the findings
obtained, key strategies can be proposed to ensure
optimal integration of AI in academic research.
1. Technical training and ongoing education.
One of the primary obstacles found was the
researchers' unfamiliarity with using AI tools.
Technical training programs that teach researchers
how to use AI prompts effectively must be
implemented if adoption is to be successful.
Programs should be easily available and
customized to researchers' different levels of
knowledge to ensure that both novices and
specialists may fully profit from new technologies.
2. Encourage interdisciplinary collaboration.
The results also suggest that collaboration between
disciplines can facilitate faster and more effective
adoption of AI. Promoting the creation of
multidisciplinary teams, where researchers with
experience in AI can collaborate with those
specialized in other areas, would help to exchange
knowledge and apply AI tools in varied contexts.
Research would be enhanced, and integration
would go more smoothly.
3. Development of infrastructure and technical
support. Adequate technological infrastructure is
important for the optimal use of AI prompts. The
study's results revealed that researchers face
technical difficulties, especially related to access
to AI platforms and software. Investing in
developing technological infrastructure, including
robust networks, accessible platforms, and
effective technical support services, will enable
researchers to use AI tools smoothly without
setbacks, thus maximizing their potential in the
research field.
4. Institutional policies that support the use of
AI. Academic institutions must adopt strategic
policies that actively promote the integration of
artificial intelligence in research processes. These
policies could include incentives for researchers
who incorporate AI-based tools in their projects,
specific funding for acquiring and updating
specialized software, and the creation of research
centers dedicated to developing and applying AI
Mujica-Sequera, R. (2025). Los Prompts de IA: Herramientas para la Optimización de la Investigación Científica. Revista Tecnológica-Educativa Docentes 2.0, 18(1), 267-
277. https://doi.org/10.37843/rted.v18i1.616
274
AI Prompts: Tools for Optimizing Scientific
Research
274
technologies in various disciplines. In addition,
institutions must foster a culture of innovation in
which AI is recognized as a transformative tool in
generating knowledge, promoting its use not only
as a complementary resource but as a key resource
for the evolution of contemporary scientific
methods and approaches.
One of the study's most significant findings was
the ability of AI prompts to facilitate the generation of
new hypotheses in research processes. Several
participants highlighted how these tools allowed them
to identify relationships between variables they had not
previously considered, streamlining the formulation of
more innovative and complex research questions. One
researcher said: "Previously, the process of formulating
hypotheses involved an extensive literature review and
manual exploratory analysis; however, with AI
prompts, I can generate multiple theoretical approaches
in a matter of minutes, which has allowed me to
diversify my lines of inquiry." Another participant
emphasized the impact of AI on the accuracy "of the
generated hypotheses, stating: Prompts not only
streamline the generation of ideas but also help
structure them with greater coherence and bibliographic
support, avoiding unfounded assumptions."
The testimonies reinforce the conclusion that AI
optimizes the time invested in formulating hypotheses
and improves the argumentative quality and analytical
depth of the research process. Thus, the study shows
that integrating these technologies has a transformative
impact on the production of scientific knowledge.
To ensure optimal integration of AI topics in
academic research, a comprehensive strategy that
combines specialized technical training and
interdisciplinary collaboration is necessary.
Convergence will allow researchers to develop
advanced skills for the efficient use of tools while
promoting the exchange of knowledge between AI
experts and specialists from various disciplines.
Likewise, advanced technological infrastructure is
required to facilitate access to AI tools and mitigate
technical barriers that could hinder their adoption.
Institutional policies play a determining role in
the process since their strategic implementation can
provide incentives, funding, and the necessary
resources to promote the widespread use of AI in
producing knowledge. Overcoming current limitations
will allow researchers to maximize the potential of AI
advisories, optimizing their studies' quality, accuracy,
and efficiency. In this sense, AI not only constitutes an
innovative resource but also redefines research
methodologies, consolidating itself as a transformative
pillar in the generation and evolution of scientific
knowledge.
Discussion
The present study answered the research question
by demonstrating that AI improves the efficiency of the
investigative process and provides significant value in
the accuracy of data analysis. The researchers involved
in the study highlighted that using the tools
considerably reduced the time spent on repetitive tasks,
such as the organization and classification of
information, allowing them to focus on critical analysis
and interpretation of results. In addition, AI prompts
revealed their effectiveness in identifying complex
patterns and relationships between variables that would
have frequently been omitted with traditional methods.
All of this translated into greater accuracy and
reliability of the results obtained. Therefore, integrating
these technological tools facilitated a significant
advance in research, improving the depth and quality of
analysis. The findings confirm that AI prompts are a
valuable resource that positively transforms the
investigative process, improving its efficiency and
accuracy.
By examining the basic relationships between
computational logic and AI applications, Nilsson's
seminal work from 1991 offers a theoretical foundation
for how AI might support scientific thinking and
information processing. Although it is an old study, its
relevance lives on in the discussion of how logical
principles embedded in AI algorithms can improve the
accuracy and depth of data analysis, which is
paramount to understanding the contribution of AI in
modern studies, such as the present one.
In studies such as Brown (2019), it was observed
that the benefits of AI prompts depend largely on the
user's familiarity with technology. The finding was also
reflected in the results of the present study, where some
researchers reported facing difficulties due to a lack of
adequate training in the use of advanced AI tools. Those
with less technological experience found it difficult to
integrate prompts into their research, which limited the
perceived benefits. According to this, when people
possess the technical know-how required to utilize AI,
its influence on research fully is considerably stronger.
Therefore, it is essential to offer continuous training and
ensure that all researchers can take advantage of the
advantages offered by AI.
Similarly, Smith (2021) and Johnson (2020)
showed that AI researchers significantly improve their
ability to formulate assumptions. That is in line with the
current study's findings, where participants emphasized
how AI-enabled them to investigate new fields by
encouraging the development of novel hypotheses and
establishing fresh paths of investigation. The study's
findings were consistent with earlier studies regarding
the improvement in data accuracy and the decrease in
analysis time. Another support for the findings of this
Mujica-Sequera, R. (2025). Los Prompts de IA: Herramientas para la Optimización de la Investigación Científica. Revista Tecnológica-Educativa Docentes 2.0, 18(1), 267-
277. https://doi.org/10.37843/rted.v18i1.616
275
AI Prompts: Tools for Optimizing Scientific
Research
275
study is that 85% of researchers observed increased
process efficiency. Additionally, 75% of participants in
this study and the other two indicated that the accuracy
of the data analysis had significantly improved.
Furthermore, Mujica-Sequera (2022) offers a
critical perspective on incorporating digital
technologies in academic research. In her study, the
author examines how digital approaches, specifically
through AI, can radically alter traditional
methodological and epistemological practices in
academic research. Mujica-Sequera (2022) highlights
that integrating AI facilitates data processing and
analysis and drives a paradigmatic shift in the
understanding and application of methodological
theories in various fields of knowledge. The innovative
approach supports and expands the present study's
findings, underlining AI's transformative capacity to
enrich and diversify research perspectives.
Recent research by Agrawal et al. (2024)
analyzed the impact of artificial intelligence prompts in
optimizing information search and prioritization,
allowing scientists to efficiently explore vast volumes
of data and facilitate more relevant discoveries. The
study offers valuable insight into the transformative
power of AI in research processes by demonstrating
how its implementation streamlines the identification of
key sources and improves the categorization and
structuring of critical information. The findings aligned
with the results of the present study show a substantial
improvement in the efficiency of data analysis using
AI-based tools.
On the other hand, Ekundayo et al. (2024) delve
into how AI is reconfiguring research methodologies in
the academic field. Their study highlights how
researchers have incorporated AI tools to overcome
traditional methodological limitations and expand the
frontiers of scientific knowledge, thus favoring the
adoption of more dynamic and adaptive approaches in
hypothesis generation and data analysis. In addition, it
is emphasized that integrating AI in research improves
the accuracy of findings and enhances the generative
capacity of researchers, promoting innovative strategies
for producing knowledge. The findings directly
corroborate the results of the present study by showing
that the use of AI prompts significantly expands
analytical capabilities and allows for more effective
optimization of cognitive and technological resources
used in the development of new research. For future
research, it is recommended to delve deeper into
integrating AI prompts in disciplines such as social
sciences and humanities, where their application is still
incipient but with considerable potential to transform
data analysis and interpretation methodologies. Areas
traditionally relied on qualitative approaches based on
subjectivity and hermeneutic analysis could
significantly benefit from AI's ability to process large
volumes of textual data, identify underlying patterns,
and generate more accurate inferences. Furthermore,
using these tools would facilitate the study of
narratives, discourses, and other corpora of information
that require complex interpretations, allowing for more
robust data triangulation and enriching critical analysis
processes.
Incorporating AI prompts in the fields of study
would not only speed up processing times. However, it
would also improve the reliability and consistency of
the results, opening new methodological and
epistemological perspectives. Likewise, its
implementation would allow for broadening research
horizons by partially automating the analysis of
historical, philosophical, and literary texts, providing
researchers with advanced tools to address research
questions more rigorously and systematically.
One aspect of particular interest would be to
explore how AI can contribute to formulating new
hypotheses in contexts where subjectivity and
interpretation play a central role, facilitating innovative
approaches to studying social, cultural, and linguistic
phenomena. It would also be relevant to examine the
ethical and epistemological challenges that emerge with
adopting AI in the disciplines, ensuring that its
integration respects the complexity and interpretive
richness inherent in the fields of knowledge.
Integrating AI in scientific research raises
profound ethical implications that must be addressed
with a critical and reflective approach. While AI
automates processes, streamlining data analysis and
hypothesis formulation, its extensive use could lead to
an over-reliance on algorithms, displacing the
researcher's critical judgment and reducing autonomy
in constructing knowledge. A central aspect of the
debate is the inherent bias in AI algorithms, as systems
learn from pre-existing data that may reflect structural
inequalities or epistemological limitations,
compromising objectivity and equity in knowledge
production. Furthermore, the standardization of AI-
generated responses could foster a homogenization of
scientific thought, limiting the diversity of approaches
and perspectives in generating new theories.
In this context, the role of the researcher in the
digital age is redefined as a critical mediator whose
function should not be limited to interpreting the results
produced by AI but to their rigorous evaluation,
questioning the validity of the findings, and ensuring
their theoretical foundation. It is imperative to establish
ethical and regulatory frameworks that regulate the use
of AI in research, promoting its integration as a
complementary tool and not as a substitute for human
reasoning in the construction of scientific knowledge.
Mujica-Sequera, R. (2025). Los Prompts de IA: Herramientas para la Optimización de la Investigación Científica. Revista Tecnológica-Educativa Docentes 2.0, 18(1), 267-
277. https://doi.org/10.37843/rted.v18i1.616
276
AI Prompts: Tools for Optimizing Scientific
Research
276
Conclusions
The present study shows how AI prompts
redirect researchers’ structure and develop their
projects, allowing for a more efficient, precise, and
systematic approach. The optimization of work hours
allows academics to spend less effort on operational
and repetitive tasks, such as data organization, and to
focus on deeper and more creative analysis. AI prompts
have also demonstrated a significant improvement in
the quality of data analysis by facilitating the
identification of complex patterns and underlying
trends that would be difficult to detect using traditional
methods. Evolution accelerates investigative processes
and increases results' reliability and reproducibility,
driving substantial advances in knowledge generation.
As technology continues to evolve, its
integration into academia is expected to become a
relevant resource in scientific research, radically
transforming the way studies are conceived and
executed. The progressive refinement of AI prompts
will allow the automation of an even greater proportion
of data collection and processing tasks, allowing
researchers to delve deeper into the critical
interpretation of findings and construct more robust
theoretical frameworks. By delegating technical
operations to advanced systems, academics can
concentrate on conceptual analysis, contextualizing
their results, and formulating new research questions,
thus strengthening the epistemological quality of their
studies. Furthermore, the continued integration of AI
will foster more fluid interdisciplinary collaboration,
enabling the development of innovative
methodological approaches and the expansion of tools
in fields that have not yet fully exploited their potential.
It will be essential for future research to explore the
impact of AI prompts in qualitative research, an area in
which its application is still incipient but with
significant possibilities for improving the analysis of
textual data, the interpretation of discourses, and the
structuring of complex narratives.
Furthermore, maximizing AI's benefits in
research requires a commitment to ongoing research
training. Specialized training in AI tools will allow their
effective adoption and a deep understanding of their
operating principles, ensuring that their integration is
not limited to an instrumental application but translates
into a substantive transformation of research
paradigms. In this sense, the development of advanced
training programs will be essential for researchers to
use AI as an auxiliary resource and actively participate
in its evolution and adaptation to the emerging
challenges of scientific knowledge.
References
Agrawal, A., McHale, J., & Oettl, A. (2024). Artificial intelligence
and scientific discovery: a model of prioritized search.
Research Policy, 53(5), 104989.
https://doi.org/10.1016/j.respol.2024.104989.
Brown, A. (2019). The impact of AI tools on the research process:
Challenges and opportunities. Journal of Advanced
Research, 28 (3), 215-227.
https://doi.org/10.1016/j.jare.2019.02.013
Creswell, J. W. (2013). Qualitative Inquiry and Research Design:
Choosing Among Five Approaches (3rd ed.). SAGE
Publications.
Denzin, N. K., & Lincoln, Y. S. (2018). The Sage Handbook of
Qualitative Research. Sage Publications.
Ekundayo, T., Khan, Z., & Nuzhat, S. (2024). Evaluating the
Influence of Artificial Intelligence on Scholarly Research:
A Study Focused on Academics. Hindawi Human Behavior
and Emerging Technologies, 8713718, 13.
https://doi.org/10.1155/2024/8713718.
Gadamer, H. G. (1997). Verdad y método. Ediciones Sígueme.
Guest, G., Bunce, A., & Johnson, L. (2006). How many interviews
are enough? An experiment with data saturation and
variability. Field Methods, 18(1), 59-82.
https://doi.org/10.1177/1525822X05279903
Glaser, B., & Strauss, A. (1967). The Discovery of Grounded
Theory: Strategies for Qualitative Research. Aldine
Transaction.
Johnson, L. (2020). AI prompts as a driving force in hypothesis
generation and data analysis. Advances in Data Science, 34
(4), 102-118. https://doi.org/10.1016/j.ads.2020.04.015
Hernández, R., Fernández, C., & Baptista, P. (2014). Metodología
de la investigación. McGraw-Hill.
Kerlinger, F. (1986). Investigación del comportamiento: Métodos
de investigación en ciencias sociales. McGraw-Hill.
Merriam, S. B. (2009). Qualitative research: A guide to design and
implementation. Jossey-Bass.
Morse, J. M. (1994). Designing funded qualitative research. In
Denzin, N. K., & Lincoln, Y. S. (Eds.), Handbook of
Qualitative Research (pp. 220-235). SAGE Publications.
Mujica-Sequera, R. M. (2022). Trascender Metodológico:
Epistemología, Perspectivas Teóricas y Metodológicas de la
Investigación Digital. Revista Docentes 2.0, 13(2), 26–36.
https://doi.org/10.37843/rted.v13i2.289
Nilsson, N. J. (1991). Logic and artificial intelligence. Artificial
Intelligence, 47(1–3), 31-56. https://doi.org/10.1016/0004-
3702(91)90049-P.
Patton, M. Q. (1999). Enhancing the quality and credibility of
qualitative analysis. Health Services Research, 34(5), 1189–
1208. https://n9.cl/ovgilb
Quivy, R., & Campenhoudt, L. (2006). Manual de investigación en
ciencias sociales. McGraw-Hill.
Mujica-Sequera, R. (2025). Los Prompts de IA: Herramientas para la Optimización de la Investigación Científica. Revista Tecnológica-Educativa Docentes 2.0, 18(1), 267-
277. https://doi.org/10.37843/rted.v18i1.616
277
AI Prompts: Tools for Optimizing Scientific
Research
277
Sandoval, C. (2002). Investigación cualitativa. McGraw-Hill.
Smith, J. (2021). Artificial Intelligence and the future of academic
research: The role of AI prompts in accelerating discovery.
Journal of Technology in Education, 17 (2), 45-60.
https://doi.org/10.1016/j.jte.2021.01.005
Strauss, A., & Corbin, J. (2002). Basics of qualitative research:
Techniques and procedures for developing grounded
theory. Sage Publications.
Taylor, S., & Bogdan, R. (1986). Introducción a los métodos
cualitativos de
